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Informational

Is it possible for Argon Welding Gas to Go Bad?

Argon gas cylinders
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On the internet, there are many myths about argon gas, one of which is that it goes bad over time. In this article, I will discuss many of these myths and will do my best to debunk them.

Argon Gas will never go bad or lose its quality on its own. However, the pressure in the gas tank might decrease with time, causing a variety of issues. E.g. You may come across a bottle that has the incorrect ratio of gas mixes. Thus affecting your weld quality and efficiency.

Even though argon gas can never go bad, there are a lot of things that you should think about before putting it in storage. If you do not store your argon in the appropriate manner, impurities will lower the quality of the argon, and it is also possible that the pressure of the gas will decrease over time.

In the following paragraphs, I will go into detail about how you can store your argon gas in an appropriate way in order to prevent it from becoming impure over time and losing pressure.

Argon Gas Never Expires

The kind of argon that is most often used during the welding process is argon 4.6. Approximately 99.96% of it is pure. Depending on the metal, argon gas may be combined with a number of other gases to mimic different bead characteristics. Nobody can predict with certainty when a tank of gasoline will deteriorate or expire.

The quality of argon-based welding gas does not diminish over time. But You need to be aware of the following facts on how argon gas behaves when being kept.

  • Time has no effect on argon gas.
  • Performance might suffer from impurities.
  • Mixed argon gas cannot be separated from it.
  • The Container May Develop Defects

Let’s look at all these aspects in detail

1. Effect of time on Argon

Time does not cause any negative changes to occur in argon. No matter how long you store the gas in the container unless your container is full of impurities. This is true regardless of how long you store it If the container is impure then it might create some problems.

2. Effect of Impurities on Argon

When you attempt to weld with argon gas that has a low purity level and you keep it in a container that has lost its shape, it is only natural that you would have poor outcomes. It’s not that the gas will go bad, but rather that the contaminants in the cylinder will make it difficult to weld.

3. Can you separate mixed Argon

There is a widespread belief that argon that has been combined with other gases will eventually become separated in the container. The reality is that this is not the case. When enclosed in a pressurized container, the mobility of molecules helps the mixture of welding gas to maintain the desired consistency.

4. Effect of container on Argon gas

Although argon welding gas does not lose its effectiveness with time, the container in which it is kept may lose part or all of its pressure. There is no stated expiration date on them, but prolonged use may significantly diminish their ability to contain argon welding gas in a suitable way. If the pressure in a gas container lowers for whatever reason, the gas stored inside the container will no longer be usable.

 As a result, frequent inspections of large cylinders are essential to ensure that they do not leak. Hydrostatic testing is a method that must be performed on gasoline storage tanks at three to ten-year intervals. You can learn more about leakage in welding gas equipment here in my other article.

What size Argon tank do I need for a MIG welder?

For hobbyist MIG welders, I’d recommend getting something between a 60 cubic-foot cylinder and a 125 Cubic foot cylinder. There is an 80 that is also accessible between 60 and 125 cubic feet. You might wanna take that into account as well.

Despite the fact that gas cylinder sizes range from 20 cubic feet to over 300 cubic feet. These sizes seem to be appropriate for you that last long enough. They are not particularly inconvenient, but they are nonetheless manageable.

How do you read cylinder markings?

Let’s talk about some of the markings that the cylinder will have. And I anticipate that many of those markers will differ across nations. Below are a few of the important stuff that is mentioned on the cylinder

  • A date that corresponds to the moment the cylinder was tested is written on it. So, in March 2003, this was tried.
  • The + then indicates that it may be somewhat overpressure.
  • The star indicates that it is valid for 10 years. If there isn’t a star, the validity period is five years.

You can read more about the cylinder markings here in this article.

welding cylinder markings and code

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How much does a cylinder of argon cost?

The price of a 60 cubic foot argon cylinder varies between $165 to $225. These prices may vary depending on your location and the time you are buying. So always do check your local store pricing before planning your project.

Although there are many variables that affect how much anything costs, this question may be quite difficult to answer. So I tried to answer this question by checking the prices of argon cylinders at three different local welding supply stores as well as online since you can now purchase gas cylinders on Amazon as well.

Below is a little chart I made outlining various shops’ costs.

[table id=11 /]

As I noted before, the cost ranges from $165 for the 60 cubic foot container on the low end to a little over $250. It cost about the same to purchase them locally and for 125 cubic feet. Therefore, I would just purchase it locally and fill it up. However, you may also take the online alternative into account.

One thing you’ll notice is that if you purchase argon gas in a larger cylinder, you’ll receive less per cubic foot gas, which makes sense since there’s some fixed cost with the exchange itself.

In terms of the exchange, I discovered that the costs of Argon and C25 gas were very comparable, so I just took the average of the costs from the two suppliers of welding supplies I contacted. I didn’t want to include one of them here as an exception since it was much higher. Therefore, after all of that, it cost around $45 to exchange one of them.

How long does welding gas long?

The amount of time you can Weld with different-sized cylinders is determined by the size of the cylinder. To give you an idea, when MIG welding, you will be using approximately 20 cubic feet per hour. So you’ll be able to Weld for about 3 hours on cylinders of 60 cubic feet. And about 6 hours on a 120 cubic foot cylinder.

Just so you know, when I say 6 hours of work, I don’t mean 6 hours of actual work. Because the majority of the time you will be working, you will not be welding.

You might get a lot more flow, especially if you’re using stainless steel. And if you’re using a back purge and a large cup, you might be able to burn through around 40 cubic feet per hour. There will also be pre and post-flow, which adds to the time. As a result, your gas will run out much faster.

Final Thoughts

I really hope that this article has helped dispel a lot of the myths surrounding argon gas. If I were to summarize the entire article, I would say that argon gas almost never goes bad as long as it is stored in the appropriate manner. The only issue with gas cylinders is the possibility that they will lose pressure over time, which will result in less pressurized gas and poor weld performance.

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Informational

How to Weld If You Have Long Hair? Pro Welder’s Tips

long hair man holding welding helmet
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Any welding operation that you perform puts you and anyone else in the area in danger of a number of different things. As a result, it is completely reasonable for you to be concerned about preventing your hair from becoming entangled in any welding equipment and posing a threat to your health. In this article, I will talk about how you can safely weld if you have long hair.

If you want to weld while having long hair, a French braid is the best option for keeping your hair together. This will help you in tying your hair and hold it together behind your neck. The French braid should keep the hair compact and close to your head’s shape, and it also allows you to wear a welding helmet. As a result, you will be able to wear full safety equipment.

When you are dealing with hot weld spatters, having long hair can present a particularly difficult challenge. Therefore, if you are interested in learning more about how you can safely weld with long hair, continue reading the rest of this article, where I will discuss the topic in greater detail and share some helpful hints.

How Your Long Hair Can be an Issue While Welding?

Welding procedures, as I indicated earlier, expose the operator as well as anybody else in the vicinity of the workplace to a wide variety of risks. A project involving welding presents a number of potential dangers and threats; it is important that you be aware of these issues in order to protect not only yourself but also others around you. Especially when dealing with spatters, it is easy for things to go wrong if you have long hair.

Before we look at all of the tips you may weld with long hair, we need to first understand the potential risks you run and everything that might go wrong. Long hair poses a unique set of challenges when it comes to welding. A few are mentioned below:

  • Spatters are your hair’s worst enemy.
  • UV rays can permanently damage your hair.
  • With long hair, grinders can cause serious accidents.

Let’s look at these problems one by one:

1. Take Spatters Seriously 

The spatter, sparks, and heat generated by the arc provides the greatest challenge throughout the welding process since they may travel up to 35 feet and enter any nearby place. You will want to provide enough protection for your long hair if you are going to be in an atmosphere like this.

Not just your hair, but everything else that might catch fire should be kept at least 35 feet away from the welding location. In addition, a fire extinguisher should never be far away. In the event that a fire breaks out.

2. UV Rays Can Damage Your Hair Permanently

Molten metals, welding arcs, and ultraviolet radiation will be present in the work environment while welding is being done. The interaction of all these factors puts you at an increased risk of serious burns. The actual welding arc may reach temperatures of up to 10,000 degrees Fahrenheit, making it one of the hottest processes possible.

And believe me when I say that you do not want that welding arc to get anywhere near your hair. Your hair will suffer a significant amount of damage as a result, and it is possible that it could even be burned.

3. Grinder Can Give You Nightmares

The usage of grinders is another factor that may create issues for your lengthy hair. Using grinders and welding go hand in hand when working with metals. Therefore, if you are a welder, you will most likely make extensive use of the grinder. And grinders are really your worst enemy when it comes to your long hair.

When you’re working, you can find yourself crouching over a grinder, which can cause serious accidents if you don’t protect your hair properly.

Tips from a Pro Welder to Protect Your Long Hair When Welding

Now you know what the most obvious dangers that you have when welding with long hair. The next step is to tell you how you can keep yourself safe from those dangers.

Here are a few of the tips that you can consider:

  • Braid your hair while welding
  • Put your hair in a tight knot behind your neck
  • Consider buying a welding cap
  • You can use a bandana too if you are a bandana lover

Let’s discuss these tips one by one:

Braid hair woman welding

1. Braiding is the Best Option You Have

Welding hoods, helmets, or shields will provide the optimum amount of protection from any sparks, heat, UV rays, flash burns, or infrared light that may be present. They will protect not only your face and neck but also your eyes and hair. As a result, I feel that acquiring one is the best approach to protecting oneself.

Welding hoods are often made of cotton or leather and are rather light in weight and can go easily along with helmets. Make sure that whichever helmet you decide to purchase, is not too heavy and that it is comfortable to wear. It must also include a spatter barrier, the ability to be modified, a sensor bar, and the availability of replacement components.

2. You Can Simply Put Your Hair in a Tigh Knot

The most conventional and easiest technique for a welder operator to keep their long hair out of their face is to pull it back into a tight bun. Wrap an elastic band over your buns and secure them in place to prevent them from falling on your face.

If there are any unruly hairs, just use bobby pins to push them up and you should be OK. Anything that prevents your hair from falling on your face will suffice.

3. Consider Buying a Welding Cap

A welding cap is a good option if you want something that is both lightweight and comfortable. It must adequately shield your head from any hot metal, sparks, or splatters that may be present.

Not only they are effective in protecting your hair, but they are also made completely of cotton, making them incredibly breathable and also preventing sweat from pouring down your eyebrows while working.

4. Bandana is Another Option That You Can Use

Braids are not easy to create for everyone, and they may even be difficult to perform on a regular basis. If you don’t know how to braid my easiest suggestion would be to put a bandana over your head and tuck all of your hair within.

When welding, sparks will fly everywhere, and this will keep you safe. Make use of bobby pins or a bun to tuck in all of the ends. Bandanas aren’t my first choice for headgear. But it works. It’s a good option to have in case you don’t know how to braid your hair.

Few Other Safety Measures That You Need to Take

In addition to your hair, there are a few other parts of your body that need your attention. Some of these essential measures for ensuring your safety are listed below:

  • Protect your eyes at all cost
  • Always keep a fire extinguisher in your shop
  • Wear protective clothing
  • Make habit of using respirators
  • Beware of leakages in your welding system
  • Keep your welding space clean

Let’s discuss them one by one:

1. Protect your eyes at all cost

Be sure to always wear safety glasses in your workplace to protect your eyes from flying debris, which is often composed of metal. If you routinely do welding tasks, you will be exposed to a significant amount of flying debris.

You should make it a routine to put them on as soon as you come in the door; this will ensure that you are protected at all times.

2. Always keep a fire extinguisher in your shop

You shouldn’t be shocked if anything catches fire at some time during a welding operation because of all of the intense heat and sparks that are produced throughout the process. Because fires are a very real risk, you should always have an extinguisher on hand in case one breaks out.

3. Wear protective clothing

If you’ve ever imagined yourself beginning your first welding project in a pair of shorts, an old t-shirt, and a pair of flip-flops, you should rethink that idea. Wearing the necessary protective clothing at all times when welding is required if you wish to prevent injuries to your body, notably burns, that may be caused by the process.

4. Make habit of using respirators

You should always wear a respirator if you are going to be dealing with metals or any other materials that have the potential to emit harmful vapors.

Welding or cutting certain materials may produce a welding plume, which is a combination of hazardous gases, fumes, and smoke. This is not the type of thing you want to breathe in if you want to keep your lungs healthy and prevent respiratory issues.

If you are interested in knowing more about respirators and their types, please check out my other article.

5. Beware of leakages in your welding system

There is a good chance that you have pressurized containers in your welding shop that hold liquids or gases. Take extra precautions to check that none of those containers or the items that you are attaching to them have any leaks in them.

See my other article to know more about leakages and how to detect them.

6. Maintain your equipment

If you want to establish the safest possible working environment for your welding projects, you need to give your equipment a lot of TLC and make sure it’s in good operating order at all times. If your welding equipment and tools are in disrepair, an accident is almost waiting to happen every time you use them. However, the vast majority of incidents of this kind are avoidable if proper care is taken with the equipment.

Wrapping it Up

When it comes to welding, safety is the most important thing to keep in mind at all times. Because because welding involves a significant amount of fire and spatters, it is essential that you take a significant amount of precaution to protect your hair. I really hope that you’ll be able to keep your hair under control while welding thanks to the advice that’s been provided in this article.

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Weld Types

Different Welding Methods: Applications of Each Method

welding techinques
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Welding is joining two pieces of metal together by melting and cooling them until they become one piece. Welding processes include:

  • Oxyacetylene welding
  • Shielded metal arc welding (Stick)
  • Gas tungsten arc welding (TIG)
  • Gas metal arc welding (MIG)
  • Flux-cored arc welding
  • Torch or oxyfuel brazing

Some methods employ both heat and pressure, while others employ only heat. Welding is commonly used to construct automobiles, airplanes, and buildings. Other metal-cutting methods, such as oxy-acetylene and plasma arc cutting, use heat or electricity to cut through metal.

1. Oxyacetylene welding

Oxyacetylene welding (OAW) is a method of joining two pieces of metal using heat generated by the combustion of oxygen and acetylene gas.

Torch brazing (TB) is similar, but the metal is not completely melted. Instead, a special alloy is melted and used to join the two metal pieces.

Oxyfuel gas cutting (OFC) is a method of cutting metal that uses the same tools and gases as OAW and TB.

To generate heat and bond the metal, all of these methods employ a torch and special gases. They are frequently used on small or thin metal pieces.

Applications:

  • Welding and brazing thin or small pieces of metal
  • Welding and brazing dissimilar metals
  • Cutting and piercing metal

Situations to Avoid:

  • Welding thick or heavy sections of metal
  • Welding high alloy or stainless steel
  • Welding in high wind or outdoor conditions (due to the open flame)
  • Welding in confined spaces (due to the production of harmful gases)

2. Shielded metal arc welding (Stick)

Shielded metal arc welding, or SMAW, is a way of welding metal together using an electrode that is coated with a special kind of flux.

The electrode melts and becomes a part of the welded metal. To do SMAW welding, you need a transformer, two welding cables, a work clamp, and an electrode holder.

There are many different types of electrodes you can use for SMAW welding, so you can choose the one that is best for your project. With SMAW welding, you can join different types and thicknesses of metal using the same machine.

Applications:

  • Welding thick or heavy sections of metal
  • Welding in outdoor conditions
  • Welding in dirty or contaminated environments
  • Welding on dirty or painted surfaces

Situations to Avoid:

  • Welding thin or small pieces of metal (more suited for TIG welding)
  • Welding high alloy or stainless steel (can affect the quality of the weld)
  • Welding in confined spaces (due to the production of harmful gases)
  • Welding in the presence of high winds (due to the electric arc)

3. Gas tungsten arc welding

GTAW, or gas tungsten arc welding, is a method of joining metal using a tungsten electrode. The tungsten electrode generates an electric arc, which melts the metal being welded as well as the end of the filler metal, which is manually applied.

Shielding gas is emitted from the welding gun to protect the molten weld metal from dirt and other contaminants. A foot or thumb switch can be added to the GTAW equipment to help the welder better control the welding.

GTAW welding produces very clean, high-quality welds, but it is slower and requires more skill than other welding methods. It is particularly useful for joining metal alloys that can only be joined with GTAW.

Applications:

  • Welding thin or small pieces of metal
  • Welding high alloy or stainless steel
  • Welding in outdoor conditions (with proper shielding gas)
  • Welding materials with high levels of contaminants or impurities
  • Welding in high-precision environments

Situations to Avoid:

  • Welding thick or heavy sections of metal (more suited for MIG welding)
  • Welding in high production environments (slower process)
  • Welding in confined spaces (due to the production of harmful gases)
  • Welding in the presence of high winds (due to the electric arc)

4. Gas metal arc welding (MIG)

Mig welding is a type of arc welding that uses a continuously supplied wire electrode and gas to weld metal together.

It is becoming more popular because it is easier to learn than other types of welding, like stick and tig welding, and it is faster because you don’t have to stop and change the electrode as often.

Mig welding also creates less slag and spatter, which makes it more enjoyable to use and easier to clean up.

However, MIG welding equipment is more expensive and the MIG gun, which is the portable part of the equipment, can be difficult to use in small spaces. Mig welding also requires a shielding gas to work, so it is not as good for outdoor use.

Applications:

  • Welding thick or heavy sections of metal
  • Welding high alloy or stainless steel
  • Welding in high-production environments
  • Welding in outdoor conditions (with proper shielding gas)

Situations to Avoid:

  • Welding thin or small pieces of metal (more suited for TIG welding)
  • Welding in confined spaces (due to the production of harmful gases)
  • Welding in the presence of high winds (due to the electric arc)
  • Welding materials with high levels of contaminants or impurities (can affect the quality of the weld)

5. Flux-cored arc welding

Flux-cored arc welding, or FCAW, is a method of joining metal using a special type of electrode wire known as a flux core wire.

The wire is fed from a spool continuously through the welding equipment and out of the gun. The welding current flows through the equipment, melting the wire and the base metal.

Some flux core wires generate their own shielding gas as they melt, while others require the use of additional shielding gas. As the wire melts, it produces a gaseous cloud that shields the weld surface and removes impurities from the molten metal.

After the weld is completed, a layer of slag must be removed from the weld’s top. Despite this additional step, FCAW is a popular welding technique because it produces high-quality welds quickly and is very versatile.

FCAW equipment is similar to that used in gas metal arc welding (GMAW), and both methods are semiautomatic, which means that the wire is fed automatically but the welder moves the gun manually. Welding supply stores and other retailers stock FCAW equipment and filler metals.

Applications:

  • Welding thick or heavy sections of metal
  • Welding in outdoor conditions (with proper shielding gas)
  • Welding in high-production environments
  • Welding in dirty or contaminated environments

Situations to Avoid:

  • Welding thin or small pieces of metal (more suited for TIG welding)
  • Welding high alloy or stainless steel (can affect the quality of the weld)
  • Welding in confined spaces (due to the production of harmful gases)
  • Welding in the presence of high winds (due to the electric arc)

Comparison Table:

Welding ProcessApplicationsSituations to Avoid
Oxyacetylene weldingWelding and brazing thin or small pieces of metal; welding and brazing dissimilar metals; cutting and piercing metalWelding thick or heavy sections of metal; welding high alloy or stainless steel; welding in high wind or outdoor conditions; welding in confined spaces
Shielded metal arc welding (Stick)Welding thick or heavy sections of metal; welding in outdoor conditions; welding in dirty or contaminated environments; welding on dirty or painted surfacesWelding thin or small pieces of metal; welding high alloy or stainless steel; welding in confined spaces; welding in the presence of high winds
Gas tungsten arc welding (TIG)Welding thin or small pieces of metal; welding high alloy or stainless steel; welding in outdoor conditions (with proper shielding gas); welding materials with high levels of contaminants or impurities; welding in high-precision environmentsWelding thick or heavy sections of metal; welding in high production environments; welding in confined spaces; welding in the presence of high winds
Gas metal arc welding (MIG)Welding thick or heavy sections of metal; welding in high production environments; welding in outdoor conditions; welding on dirty or painted surfacesWelding thin or small pieces of metal; welding high alloy or stainless steel; welding in confined spaces; welding in the presence of high winds
Flux-cored arc weldingWelding thick or heavy sections of metal; welding in high production environments; welding in outdoor conditions; welding on dirty or painted surfacesWelding thin or small pieces of metal; welding high alloy or stainless steel; welding in confined spaces; welding in the presence of high winds
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