71 Welding Carbon Steels
David Colameco, M.Ed.
Basics of welding carbon steels
The majority of carbon steels will come in shapes you are familiar with or will become familiar with while welding and fabricating. Plates, pipes, H-beams, and C-channel for example are common shapes you will use to fabricate. As a welder and fabricator, the WPS and blueprints will provide you with the instructions you need to complete the fabrication to the required specifications. If the WPS or blueprint has something that isn’t clear to you, stop and ask a colleague or supervisor for clarification. Spending a few minutes to clarify something is better than spending an hour or more on rework.
Steels can be hot rolled, cold rolled, quenched and tempered, or processed in other ways to achieve the desired properties. When you weld, you are destroying those treatments and mechanical workings of the base material because the metal melts within the weld pool returning the metal to its original state prior to treatment. In areas where the base material does not melt, there is a heat affected zone (HAZ) where grain growth, allotropic changes, and absorption of elements into the crystal structure can occur. The heat applied to the base metal in the HAZ will change the mechanical properties of the base material and/or result in a weld with material properties that are less than desired. The end result could be failure of the weld joint due to cracking which is why following a WPS is so important. If a structural failure occurs, as welders we want that failure to occur in the base material away from the weld and not because of the weld.
The HAZ is a complex set of sub zones shown in the V-Groove Butt Joint of Figure 20.6 below. The weld metal is at the center, followed by a penetration zone directly next to the weld metal which represents the melted base material that fuses with the weld metal. Moving further outward we next reach the coarse-grained HAZ that experiences elevated temperatures from welding but not hot enough to melt the metal. In this zone the heat causes the metal grains to grow becoming more coarse. The further away we move from the weld bead itself the less heat there is in the base metal due to dissipation of heat. The Fine-grained HAZ has grains that are affected by the heat but grow to a lesser extent. This zone may have been tempered from the heat. Outside of the fine grained HAZ is the base metal which may have been heated up, but has not undergone any mechanical property changes. It is important to note that other sources may break up the HAZ into a more detailed structure. For the purposes of this chapter, this level of detail in the HAZ is adequate.
Steels from the mill are processed through cold and hot rolling. Rolling is a process where the steel is forced through rollers to flatten it out. Finer grained steel structures have a higher toughness. Figure 20.7 shows two metals being rolled together. The process for cold and hot rolling a single piece of steel is similar.
Figure 20.8 below shows a hot ingot that is being sent to a hot rolling process. This ingot of steel will be sent back and forth through a set of rollers that will gradually get closer together so the steel flattens out.
Figure 20.9 shows the results of the hot rolling process that has occurred to the ingot pictured in Figure 20.9.
These cold and hot rolling processes break the larger grain structures into a finer grain structure. Welding on steels that have been cold or hot rolled to form finer grains will result in a coarse grain structure in the HAZ. Post Weld Heat Treatment (PWHT) will relieve some of the residual tensile stresses that exist from the weld metal shrinking after it cools. Temperatures for PWHT are carefully controlled in duration and magnitude based on the base material. Too high a temperature can transform the metal’s crystalline structure into something undesirable where there is a loss of strength, or being held for too long can cause grain growth which results in reduced toughness.
Because of these changes that occur due to the heat of welding to the surrounding base metal, it is important to follow all of the temperatures and other parameters and techniques listed on the WPS.
Whenever you are welding, you should generally know which metal or metal group you are welding on for a more successful weld. Ideally you would know the metal composition because the metal is labeled in one form or another, or can be determined by a device called a spectrometer which will analyze the metal by its light emissions. Figure 20.10 shows a similar but larger hand held spectrometer used for analyzing metal but is used to analyze pavement.
One property of metal which may be useful to the welder in identifying the type of steel they have in front of them is a file test. Table 20.1 contains information to help identify which type of steel you have based on its Brinell hardness which is one hardness scale used by metallurgists to rank the hardness of metals. The hardness of steel in Table 20.1 was able to be determined based on the hardness of a standard steel file with that of the metal being tested. Iron becomes steel with the addition of carbon.
|
File Reaction |
Brinell Hardness |
Type of Steel |
|---|---|---|
|
File bites easily into metal |
100 BHN |
Mild Steel |
|
File bites into metal with pressure |
200 BHN |
Medium Carbon Steel |
|
File does not bite into metal except with extreme pressure |
300 BHN |
High Alloy Steel – High Carbon Steel |
|
Metal can only be filed with difficulty |
400 BHN |
Unhardened Tool Steel |
|
File will mark metal but metal is nearly as hard as the file and filing is impractical |
500 BHN |
Hardened Tool Steel |
|
Metal is harder than file |
600 + BHN |
Unable to determine |
Note. From Operator’s Circular Welding Theory And Application TC 9-237 (Table 7-6), by the U.S. Army (1993).
Table 20.2 lists the carbon contests of steel and cast iron for comparison.
|
Item |
Approximate % of Carbon |
Condition of Incorporated Carbon |
|---|---|---|
|
Pig Iron |
4 |
Free and Combined |
|
White Cast Iron |
3.5 |
Mostly Combined |
|
Grey Cast Iron |
2.5 to 4.5 |
0.6 to 0.9% free 2.6 to 2.9% combined |
|
Malleable Cast Iron |
2 to 3.5 |
Free and Combined |
|
Tool Steel |
0.9 to 1.7 |
All Combined |
|
High Carbon Steel |
0.5 to 0.9 |
All Combined |
|
Medium Carbon Steel |
0.3 to 0.5 |
All Combined |
|
Cast Steel |
0.15 to 0.6 |
All Combined |
|
Low Carbon Steel |
Up to 0.3 |
All Combined |
Note. From Operator’s Circular Welding Theory And Application TC 9-237 (Table 7-7), by the U.S. Army (1993).
Another identification test that can be performed in the shop is a spark test that is conducted by grinding a metal sample on a grinding wheel and observing the sparks. Figure 20.11 below shows a black and white image of spark test results, color images are available online through an internet search.
|
Metal |
Volume of Stream |
Relative length of stream (inches) |
Color of stream close to wheel |
Color near the end of the stream |
Quantity of Spurts |
Nature of Spurts |
|---|---|---|---|---|---|---|
|
Wrought iron |
Large |
65 |
Straw |
White |
Very few |
Forked |
|
Machine Steel (A1S1 1020) |
Large |
70 |
White |
White |
Few |
Forked |
|
Carbon Tool Steel |
Moderately Large |
55 |
White |
White |
Very Many |
Fine, repeating |
|
Grey Cast Iron |
Small |
25 |
Red |
Straw |
Many |
Fine, repeating |
|
White Cast Iron |
Very Small |
20 |
Red |
Straw |
Few |
Fine, repeating |
|
Annealed Malleable iron |
Moderate |
30 |
Red |
Straw |
Many |
Fine, repeating |
|
High-Speed Steel (18-4-1) |
Small |
60 |
Red |
Straw |
Extremely Few |
Forked |
|
Austenitic Manganese Steel |
Moderately Large |
45 |
White |
White |
Many |
Fine, repeating |
|
Stainless Steel (Type 410) |
Moderate |
50 |
Straw |
White |
Moderate |
Forked |
|
Tungsten-Chromium Die Steel |
Small |
35 |
Red |
Straw |
Many |
Fine, repeating |
|
Nitrided Nitralloy |
Large (curved) |
55 |
White |
White |
Moderate |
Forked |
|
Stellite |
Very Small |
10 |
Orange |
Orange |
None |
Not Applicable |
|
Cemented Tungsten Carbide |
Extremely Small |
2 |
Light Orange |
Light Orange |
None |
Not Applicable |
|
Nickel |
Very Small |
10 |
Orange |
Orange |
None |
Not Applicable |
|
Copper, Brass, Aluminum |
None |
Not Applicable |
Not Applicable |
Not Applicable |
None |
Not Applicable |
Note. “Operator’s Circular Welding Theory And Application”. TC 9-237. Department of the Army, 1993. Pp. 7-13.
Lastly, the chip test is conducted by using a sharp cold chisel to remove material. Material may be small broken pieces or one long strip.
|
Metal |
Chip Characteristics |
|---|---|
|
White Cast Iron |
Chips are small, brittle fragments. Chipped surfaces not smooth |
|
Gray Cast Iron |
Chips are about ⅛ inch in length. Metal not easily chipped; therefore, chips break off and prevent smooth cut |
|
Wrought Iron Low Carbon and Cast Steel |
Chips have smooth edges. Metal is easily cut or chipped, and a chip can be taken off as a continuous strip |
|
High Carbon Steel |
Chips show a fine grain structure. Edges of chips are lighter in color than chips of low-carbon steel. Metal is hard but can be chipped in a continuous strip. |
Note. From Steelworker, Volume 1, NAVEDTRA 14250 by NETPDC, (Table 1-4), 1996, U.S. Navy.
The table above describes the chip characteristics of different cast irons and steels. This is useful information if you have an unknown metal that you may think is cast iron or steel and are looking for a relatively easy way of determining its type.
Knowing the temperature of steel is important to a welder. Accurate measurements of metal surface temperatures can be taken using a hand held industrial infrared thermometer, using heat sticks to determine if the temperature has exceeded the value of the stick material, or by the least accurate method of visually observing the color of the steel. Table 20.5 below provides the colors steel may emit at different temperatures.
|
Color |
Temperature (°F) |
Temperature (°C) |
|---|---|---|
|
Faint red visible in dark |
750 |
399 |
|
Faint red |
900 |
482 |
|
Blood Red |
1050 |
565 |
|
Dark Cherry |
1075 |
579 |
|
Medium Cherry |
1250 |
677 |
|
Cherry or Full Red |
1375 |
746 |
|
Bright Red |
1550 |
843 |
|
Salmon |
1650 |
899 |
|
Orange |
1725 |
940 |
|
Lemon |
1825 |
996 |
|
Light Yellow |
1975 |
1079 |
|
White |
2200 |
1204 |
|
Dazzling White |
2350 |
1288 |
Note. From Steelworker, Volume 1, NAVEDTRA 14250 by NETPDC, (Table 2-1), 1996, U.S. Navy.
Uses of carbon steels in industry today
Everything from buildings, ships, bridges, railroads, cars and trucks, shelves, home appliances such as washing machines and dryers, water heaters, pressure vessels, tanks, pipes, and many more daily-used items that improve our everyday lives are made out of carbon steels or have carbon steel components.
Figure 20.12 below shows the uses of steel in a large building. Notice the size of the small trailer in the middle of the structure on the ground.
Figure 20.13 below shows a steel ship being built.
Figure 20.14 shows railcars and presumably a railroad that they are riding upon, which is also made of steel.
Other uses of steel are for cars and trucks. The sanitation truck in Figure 20.15 above is made of steel and is welded. Figure 20.17 shows two bridges, where the one on the left was built in the 1920’s while the one on the right was built in the 1990’s. Notice how the new bridge uses the same construction style to match the old bridge.
Figure 20.17 above shows a steel pipeline being constructed. Figure 20.19 below shows a steel water tank in green being used for the local towns water supply.
Welding processes used with carbon steels in industry today
The following list is not exhaustive but is a list with the welding processes you will encounter as a student in your technical program for welding carbon steels. Generally speaking all welding processes at your local community college or vocational school are applicable to welding carbon steels. Table 20.6 below offers a very general overview of how the processes are used, but remember there are always exceptions to generalizations.
|
Welding Process |
General Use |
|---|---|
|
SMAW (Stick) |
General Use: Fabrication in shop and field, repairs, tack welding |
|
FCAW-G (Flux Cored Gas Shielded) |
Fabrication in the shop, repair, used on dirtier parts |
|
FCAW-S (Flux Cored Self-Shielded) |
Fabrication in the field, repair |
|
GMAW (MIG) |
Fabrication and repair on clean surfaces |
|
GMAW-S (MIG Short Circuit) |
Fabrication and repair on clean thin surfaces |
|
GTAW (TIG, Heliarc) |
Fabrication and repair of all metals including welds requiring high quality such as specialty alloys and critical welds |
|
SAW |
Fabrication of thick materials in heavier industries such as bridge building, pipe fabrication, and very large fabrications. |
Note. Heliarc is the original trade name by the Union Carbide Corporation
It is important that you learn to use as many welding processes as possible while in your welding program because many processes are used together in industry such as using GTAW for root passes followed by SMAW on pipe welding. These next few sections provide a high level overview of the welding processes. Please see the chapters on these welding processes for more information.
Shielded Metal Arc Welding (SMAW)
Shielded Metal Arc Welding is a tried and true welding process that has relatively inexpensive equipment that can get into tight spaces to weld. The process has various electrode types of different alloys, tensile strengths, and sometimes hydrogen contents. Low hydrogen electrodes are used for applications where cracking is an issue such as when welding thick base materials. If low hydrogen electrodes are not used, that hydrogen may not have enough time to diffuse out of the base material which could lead to cracks. Use of low hydrogen electrodes and even a post weld heat treatment may be used to reduce and remove hydrogen from the weldment. Chapter 8 discusses SMAW in detail.
Gas Metal Arc Welding (GMAW)
Gas Metal Arc Welding (GMAW) is a process that does not produce a slag, is a higher deposition process than SMAW meaning that it can lay down more weld. GMAW has the ability to deposit more weld metal than SMAW due to the filler wire being continuously fed into the welding gun with the pull of the trigger. The drawback of GMAW is that it suffers from being susceptible to air drafts which does not make it a good candidate for field welding. Air drafts will blow away the shielding gas that is needed to protect the weld metal while it is hot from the elements such as nitrogen and oxygen that are in the air which will result in porosity in the weld. Chapter 10 discusses GMAW in detail.
Flux Cored Arc Welding (FCAW)
Flux Cored Arc Welding is a semi automatic wire feed process that is being adopted by welders in the field. This process has a self shielded and a gas shielded variation. The self shielded FCAW, or FCAW-S, is similar to SMAW in that the electrode contains flux material that shields the weld from the air. The other variation is FCAW-G which uses a cored electrode that has a flux in it and a shielding gas which together protect the weld from the air.
One question that might be asked is “Can I use a FCAW-S wire with a shielding gas if I run out of FCAW-G wire?” You certainly could set up a machine to do this, but it is not advised because the elements that are in the FCAW-S wire will not react with the air to form a slag as they are intended and will instead end up in the weld pool which will likely negatively affect the chemistry of the weld and in turn the mechanical properties of the weldment. This is similar to hauling construction materials in a compact car vs. a truck; you can do it but unintended damage is likely to occur. If it is a code weld, you can not use FCAW-S wire because it is not listed on the FCAW-G WPS.
The benefits of using FCAW are that it has a higher deposition rate and it can be considered a low hydrogen process even though the hydrogen levels in the electrode are not as low as some low hydrogen SMAW electrodes. The downside to FCAW is that it may not have the versatility that SMAW has for tight spaces, and the welding machine needs to be close by because longer welding leads will suffer from worn out liners because the wire will rub more on the liner as it makes its way through the lead. Chapter 9 discusses FCAW in detail.
Gas Tungsten Arc Welding (GTAW)
Gas Tungsten Arc Welding (GTAW) is also used to weld carbon steels. This process produces high quality welds due to the control the welder has over the heat input and the general welding process. These welders are highly trained professionals.
The downside to GTAW is that it is not a field welding process and is typically done in a shop due to the shielding gas being susceptible to drafts blowing it away. Like FCAW, the welding leads are short because the welding machine is typically close by. Also GTAW suffers from a low deposition rate and would take a very long time to fill groove welds that are easily filled by SMAW, FCAW, and GMAW. For this reason, GTAW might be used for the root pass of a groove weld in a pipe butt joint, while the interpasses and cover passes are welding using another process. This is an important example as to why you should be learning as many processes as you can at school because it is not uncommon to find multiple processes being used together. Chapter 11 discusses GTAW in detail.
Other Processes
As mentioned in the previous section for GTAW, sometimes multiple processes are used together such as a GTAW root pass on a pipe weld, followed by SMAW. Sometimes even GMAW and FCAW can be used in succession. If you have a particular welding industry in mind to work in upon graduation, it is highly recommended that you intern at a company or at the very least go on a company tour and find out what welding processes they use. You might be surprised and find that you should learn an additional process you didn’t think was used in that industry.
While not covered in this book due to its limited instruction in community colleges, Submerged Arc Welding (SAW) is a process that is used to weld thick pieces of carbon steel together in bridge building, and construction of very large weldments making it worthwhile to introduce to you since you may find it during your welding career. The process uses a granular flux and is welded in the flat and horizontal positions only. Welding in the horizontal position requires the use of barriers that keep the flux covering the weld pool because the flux would otherwise fall out of the weld joint.
Figure 20.19 below shows a submerged arc weld being performed on a very large weldment for underwater wind turbine foundations shown in Figure 20.21. Notice the granular flux that is used which protects the weld. This flux is typically low hydrogen and must be kept in an oven at about 150 °F to up to 550 °F. As with the name, the arc is submerged and you cannot see it. SAW is a neat process to use that you should try out if given the opportunity.
The flux in Figure 20.17 above is covering the hot weld bead. Sometimes this flux will be recycled. Note that the welding does not emit fumes or smoke through the flux. SAW is used primarily on thick materials and can be used to make I-Beams and pipes.
This section discussed the uses of carbon steel and the different welding processes used to weld it. The most important thing to note is how important it is to learn more than one welding process because you may have to use multiple processes at a time during your career. Welding pipe with a GTAW root followed by SMAW interpass and cover passes is a great example.
Attributions
- Figure 20.6: Weld Heat Affected Zone by Nicholas Malara, for WA Open ProfTech, © SBCTC, CC BY 4.0
- Figure 20.7: Rolling Cladded Steel by Nicholas Malara, for WA Open ProfTech, © SBCTC, CC BY 4.0
- Figure 20.8: Heat 67-V1-83 being hot rolled prior to first pass by U.S. Department of Transportation, Federal Highway Administration in the Public Domain; United States government work
- Figure 20.9: Heat 67-V1-83 being hot rolled after last pass by U.S. Department of Transportation, Federal Highway Administration in the Public Domain; United States government work
- Figure 20.10: Handheld XRF spectrometer by U.S. Department of Transportation, Federal Highway Administration in the Public Domain; United States government work
- Figure 20.11: Characteristics of sparks generated by the grinding of metals by Headquarters, Department of the Army in the Public Domain; United States government work
- Figure 20.12: Field-assembled building by U.S. Department of Labor, Occupational Safety and Health Administration in the Public Domain; United States government work
- Figure 20.13: Shipbuilding and Ship Repair by U.S. Environmental Protection Agency in the Public Domain; United States government work
- Figure 20.14: Sealed steel containers are loaded onto railcars at the Moab Uranium Mill Tailings Remedial Action Project site in preparation for transport of uranium mill tailings to the Crescent Junction disposal cell, 30 miles north of Moab. by U.S. Department of Energy, Office of Environmental Management in the Public Domain; United States government work
- Figure 20.15: Airflow Deflector Side Guard by U.S. Department of Transportation, Federal Highway Administration in the Public Domain; United States government work
- Figure 20.16: View of the historic (left) and modern (right) Navajo Bridge by U.S. Department of the Interior, National Park Service in the Public Domain; United States government work
- Figure 20.17: A pipeline being lowered into the trench by U.S. Department of Transportation, Pipeline and Hazardous Materials Safety Administration in the Public Domain; United States government work
- Figure 20.18: Erwin Water Storage Tank Replacement by U.S. Environmental Protection Agency, Office of Ground Water and Drinking Water in the Public Domain; United States government work
- Figure 20.19: UP schweissen WEA 00037 by Martinhannes is released under CC BY-SA 4.0
Industries That Use Welding
The main industries that you can build a welding career in are manufacturing (production or custom), maintenance and repair, construction, maritime, and pipelining. However, many careers or occupations may utilize welding yet not be classified as a so-called "welding career." For example, an automotive or diesel mechanic may be expected to perform welding as part of their job, though that is not their primary responsibility. And in the construction industry, ironworkers, piledrivers, millwrights, and other tradespeople may be expected to have the ability to weld.
According to Zippa (2023), welders work in a variety of industries:
- 31% work in manufacturing,
- 14% are considered “professional,”
- 10% work in construction,
- 9% work in the transportation industry,
- 7% work in automotive,
- 5% work in technology,
- 4% work in energy,
- and the rest work in a variety of industries ranging from retail to education.
As you learn about welding while reading this book and consider which industry you wish to work in, ask yourself some questions. First, which welding process might you prefer to work with? FCAW is commonly used in construction, maintenance and repair of equipment, building facilities, and in the maritime industry. FCAW, gas metal arc welding (GMAW), and GTAW are commonly used in manufacturing and custom fabrication work. GTAW and shielded metal arc welding (SMAW) are commonly used in pipe welding.
The next question to consider is in regards to your temperament—what would you want in a welding job? For instance, working in construction may pay well, often requires you to work in inclement weather, may offer less job predictability, is often hazardous, and frequently involves travel. Working in manufacturing usually offers more consistent work hours, is inside work, and allows you the consistency of going to work at the same shop each day. Manufacturing tends to be repetitive but provides fairly stable employment. Custom fabrication is similar to manufacturing with the added challenge of building unique items per blueprint specifications, often requiring welders to have extensive creativity and problem-solving skills. Pipe welding is considered a specialty and requires a high degree of welding skill, frequently accompanied by higher pay rates. Working as a pipeliner often means traveling to jobsites with your own welding machine and other required tools.
No matter the direction you choose for a career path, a solid education in welding and the ability to weld with different processes not only increases your employability but also allows you to move between industries. A skilled welder can usually find a job almost anywhere.
In Washington state, welding job opportunities vary by region. On the coast and in the Puget Sound region on the western side of the state, there are numerous shipyards. In urban areas, the construction industry has been steady despite national fluctuations in the economy. Statewide, there are many manufacturers that employ welders, both in production and in building/plant maintenance realms. Many vendors supply the aerospace industry with fabricated components, too. There is also the potential for self-employment as a mobile repair or fabrication welder serving agriculture, industry, and the community at large.
Essay by April Cyaltsa Finkbonner
My name is April Cyaltsa Finkbonner and I am a journeyman ironworker from Local 86, Seattle, WA. I joined the ironworkers apprenticeship in 1995 and I am currently a welding instructor for the Local 86 apprenticeship program.
I was introduced to welding in my early twenties when my dad was doing some repair work on our commercial fishing boat. I was curious about what he was working on, and he said, “Grab that hood and come watch me.” After he finished welding a broken piece back together, I said, “Wow, that was cool.” He said, “You should look into welding. They say women make pretty good welders with their steady hands.” At that moment, I was immediately hooked on welding. I took his advice and registered at a technical college for a nine-month welding course. It was there that I found that FCAW was my favorite welding process. My welding instructors were suggesting that I pursue an apprenticeship program. I wanted to know what trade welded a lot with the self-shielded FCAW process, and they said, “The ironworkers.” I asked, “And what do they do?” My instructor replied, “They build bridges and skyscrapers and stuff.” I said, “Oh yeah? That’s what I want to do!”
So, I joined the ironworkers with my FCAW certification in hand. As an apprentice, I was able to take some of the welding dispatches that were not able to be filled by the journeymen, which meant that I was able to receive journeyman’s pay. As a journeyman, I invested most of my ironworker career as a production welder. In 2005, I was recruited to be a welding instructor for the apprenticeship and I consider myself blessed to have the opportunity to teach what I love.
I highly encourage people who like to work with their hands to take a welding course and learn all of the different processes. They’re bound to find something that piques their interest. Once you have the welding skills, the career possibilities are endless, especially for the creative minds. “If you need it, you can weld it. If you can imagine it, you can weld it.”
The opportunities are vast when you own the technical skills of welding.
Developing Industries and Technologies
As stated previously, there are over a hundred different welding processes today, with more in development. While most welders perform manual welding or semiautomatic welding, there are many career opportunities in specialized, high-tech welding.
Additive Manufacturing (AM) is quickly gaining ground in the industry. Complex metal parts can be precisely fabricated with different forms of additive manufacturing. Some resemble 3D printing, using a wire feeder and an electric arc or laser to continually melt and fuse the filler metal to the previous deposit. Other forms of AM use a metal powder that is melted with a laser in specific places, then covered with a layer of more metal powder, melted by laser to the previously melted metal, covered with another layer, etc., until the object is created.
Robotic welding has been around for decades, changing automotive manufacturing into an almost completely automated process. However, the cost of purchasing and maintaining robots as well as quality control issues in production have limited their use. Operators of robotic welders typically monitor the robot’s performance and perform welding repairs to any defects in the robot’s work.
Computer Numerically Controlled (CNC) welding incorporates computer control of robotic or automatic welding and may integrate the welding machine into other machining during the manufacturing process. For instance, metal parts may be loaded into the machine and then automatically welded and machined per the computer program.
The skills and training required to operate these various systems will influence the welder's pay rate. Less training and skill required will likely mean lower wages, while more training and skill will likely ensure higher salaries for the welding operator.
With the increase of robotic/automatic welding process jobs, there will be a need for a skilled workforce to operate the equipment. However, we are still a long way away from a robot replacing people climbing a ladder and welding connections in a building or crawling around in a ship’s bilge to patch a hole in a leaky fuel tank.
Niche or “Boutique” Jobs
Along with the emerging automated welding jobs there are also opportunities in specialized careers. Due to the high level of skills and training required and the limited pool of available labor, some of these can pay quite well.
Commercial diver-welders may work underwater, though welding is performed “in the dry” whenever possible. Pay rates can be high because there are a limited number of workers in the field, the hazards inherent in the work, and the expense of required training. Careers in commercial diving and underwater construction are challenging and rewarding due to the job's physical demands.
Many artists use metal as a sculptural medium and employ welders, blacksmiths, and other helpers in their studios. Like other artists, one’s income depends on the success of selling the art produced and the amount of money patrons are willing to invest in the artist and studio.
Restoration of classic cars or custom fabrication of cars requires the ability to work with thin metals and produce not only safe but visually unidentifiable welds. If new body components like fenders are added or modified, the welded seams must be invisible after painting. Frames or roll bars of race cars must be strong enough to endure the constant punishment of a track or off-road race without failing. Welding of custom exhaust headers must be leakproof and aesthetically pleasing.
Creating custom architectural features such as fireplace surrounds, exotic handrails, or furniture requires a high level of fabrication skills, including blueprint reading, precise layout, and quality welding. Many welds will be visible on the finished product and must be uniform and strong. Attractive welds are frequently preferred over welds that are ground flush and hidden.
Privatized space travel and emerging space tourism have opened up new jobs in the aerospace industry, not only in fabricating parts for spacecraft but in the building infrastructure and jig assemblies required to facilitate constructing spacecraft.
What Employers Look For When Hiring
Of course, employers desire specific welding and fabrication skills, namely time in the trade (journeymen level represents several years of experience). They usually administer pre-employment skills testing through a welding or fabrication test to verify your skills. Jobs requiring welding certifications or proficiency in multiple welding processes often pay more than jobs that do not.
Usually employers focus on only one or two welding processes and only expect their employees to show proficiency in those processes. Custom fabrication shops are the jobs that most likely expect welders to be proficient in multiple welding processes, like SMAW, GTAW, GMAW, and FCAW. However, this is not expected in every fabrication shop. The obvious advantage of attending a trade school or college for welding training is that you are more likely to receive training in multiple processes, thus increasing employability.
Fabrication, or “fitting,” is a skill distinct from welding. While fabricators use welding, their main task is to read and interpret blueprints and use that information to build the assembly described in the blueprint. The fabricator may weld the assembly or simply tack it together with small welds for a welder to complete welding afterward. Fabricators must be able to read tape measures to the one-sixteenth of an inch, use other measuring tools, accurately mark and cut out parts, build jigs and fixtures to facilitate building multiple assemblies at a time, and safely use various hand and power tools. In short, employers depend on a fabricator to be able to look at a blueprint and create the object in real life.
While training for a career in the welding industry, developing strong welding and fabrication skills is essential. Today, these soft skills are also becoming a high priority with employers:
- good attendance,
- social skills,
- ability to receive training and feedback,
- openness to working with diverse groups of people,
- capacity to clearly communicate (orally and in writing), and
- knowledge for how to use technology to find work-related information.
Make good attendance a priority and arrive early enough to start on time. The best welder in the world is useless to their employer if they are not at the jobsite welding. Avail yourself of opportunities to take diversity, equity, and inclusion training to learn about others and develop a self-awareness of how your words and actions impact others around you. The world's best welder has increased value if they can get along well with their coworkers. Typically, a degree in welding requires you successfully complete other academic classes such as English and psychology—it is advantageous to view these classes as opportunities to develop the communication and social skills that employers value. The same is true of computer literacy courses: manufacturing more and more uses CNC and other computer-controlled processes, and even the construction industry is using tablets in the field for functions such as accessing digital blueprints and recording data (including the hours you work and expect to be paid for).
Attributions
- Figure 1.6: © used with permission
- Figure 1.7: Sculptor Heather Jansch next to her work "The Young Arabian" by Kieronjansch is released under CC BY-SA 4.0
- Figure 1.8: SpaceX In-flight Abort Illustration by SpaceX is released under CC0
- Figure 1.9: Punch Clock by Tom Blackwell is released under CC BY-NC 2.0
- Figure 1.10: image released under the Pexels License
Overview
The first mass use of industrial welding of steels occurred in United States shipyards during the 1940’s in support of the war effort for World War II. This was a major undertaking where shipbuilders, such as Kaiser Shipyards, built their ships with welded joints instead of rivets. The value of the efforts and heroism of the women, including minorities, who stepped up in support of the war effort can not be understated. This was not easy. The US Government campaigned and convinced companies to hire women for manufacturing positions. These courageous women were not only facing increased responsibilities due to family members and loved ones being sent overseas to fight but were also facing the dangers from a new industrial environment that did not have the regulations from OSHA that we have today. They turned out thousands of ships that were pivotal in winning World War II. When our country’s fighting force returned to the US, many of the women who wanted to remain welders were forced to give up their jobs to provide job openings. What struggles and challenges do you face that are similar to those who came before us?
Today our welding industry continues to benefit from the efforts of a diverse workforce. While we acknowledge the sacrifices and wrongs of the past we must recognize the progress we have made and look towards the possibilities of the future. Many advances have been made in welding since the 1940’s in welding machines, materials, joint designs, our understanding of welding defects, and filler metals to name a few that make it possible to fabricate for extreme in-service conditions. This chapter will discuss welding various ferrous (iron based) metals that includes their properties, common welding processes, filler metals, and uses in industry today.
Objectives
After completing this chapter students will be able to:
- Explain the properties and best practices of welding carbon steels
- Explain the properties and best practices of welding stainless steel
- Explain the properties and best practices of welding cast iron and cast steel
Key Terms
- Brazing
- Carbon Steel(s)
- Chromium
- Chrome-Moly - Chromium Molybdenum Alloy
- Deposition
- Ferrous Metal
- Heat Affected Zone
- In-Service Conditions
- Interpass Temperature(s)
- Oxy-Acetylene
- Preheat
- Soldering
- Stainless Steel
- Welding Metallurgy
Attributions
- Chapter opening image: GMAW in use by U.S. Department of Transportation, Federal Highway Administration in the Public Domain; United States government work
Overview
Whether you are welding a root pass on high-pressure piping, the intake on a Boeing 747, or building a bicycle frame, you want maximum control to ensure you produce as flawless of a weld as possible. This is where gas tungsten arc welding (GTAW) comes in. This process lets you manipulate the molten weld puddle from the palm of one hand with a high degree of accuracy using a non-consumable tungsten electrode (meaning the tungsten does not become part of the weld). Increasing and decreasing the amperage/current as you are welding also gives the welder a unique amount of control.
GTAW is also known as tungsten inert gas (TIG) welding, and some welders may still use the term “Heliarc” welding for the process’ use of helium. Argon and helium are used as shielding gasses to protect the molten weld puddle from contaminants in the air. These gasses can be used separately (100% argon or 100% helium) or as a mixture.
This chapter covers the many variables of GTAW, including the process, how it is used in the industry, and how to develop your skills using it. Most importantly, we will review how to maintain a safe working environment while using this process.
Objectives
After completing this chapter, students will be able to:
- List the uses of the GTAW process in industry.
- Identify equipment associated with GTAW.
- Comprehend GTAW-specific safety concerns.
- Recall settings and techniques for using GTAW.
- Classify electrodes, filler metals, and shielding gasses used for GTAW.
Key Terms
- Autogenous weld
- Distortion
- Inert gas
- Laminar flow
Attributions
- Chapter opening image: SIGONELLA, Sicily (July 15, 2009) Aviation Support Equipment Technician Airman Anthony Hammond, from Ft. Washington, Md. assigned to the aircraft intermediate maintenance department at Naval Air Station Sigonella, performs tungsten inert gas welding during a training evolution. by Mass Communication Specialist 2nd Class Jason T. Poplin in the Public Domain; United States government work
- Figure 11.1: Tungsten Arc Welding by Master Sgt. Matt Hecht in the Public Domain; United States government work
