In welding, "melt through" occurs when excessive heat causes the base metal to be penetrated, resulting in a hole. "Burn through" happens when the heat is so intense that the molten metal actually burns away portions of the base metal, leading to thinning or complete loss of material. Both defects can weaken the weld joint and compromise its integrity.
Oxidation can negatively impact the quality of welding by weakening the bond between the metals being joined. This can lead to a weaker and less durable weld, as well as potential defects and imperfections in the final product. It is important to prevent oxidation during the welding process to ensure a strong and reliable bond between the metals.
Oxidation is a chemical reaction where a material loses electrons. In welding, oxidation can weaken the bond between the metals being joined, leading to a weaker weld. It can also cause defects in the weld, such as porosity or cracks, reducing the overall quality and strength of the weld.
Shielding gases in welding protect the molten metal from reacting with the surrounding air, which can lead to defects like porosity and oxidation. They also help stabilize the arc and improve the quality of the weld by controlling the heat input and transfer.
The Oxy-acetylene flame is much hotter and the preferred combination for the welder especially when welding pipe and plate metal. Somewhat of a rare welding procedure in modern times. Replaced by arc welding. Liquid Propane Gas burns cooler and is preferred by employers as it is cheaper. Not bad results on light gauge material, again takes longer to heat up. -RedSeal Welder
Oxidation can weaken welds by forming brittle and porous areas, reducing the strength and integrity of the joint. This can lead to defects and failures in the welded structure.
When we are using the tig welder we getting welding defects on our blanks, but when using the plasma weld no defects are found
what is the difference between ultrasonic welding & radiographic welding
The prehaet temperature is taken before welding starts. The interpass temperature is taken between welding passes.
back hand welding is when you pull the welding rod or whatever it is that you are using and forehand is when you push it ahead
Pressure welding uses pressure to create the bond between two materials, while fusion welding relies on melting the materials to create the bond. In pressure welding, the materials are pressed together under high pressure, while in fusion welding, the materials are melted together through the application of heat.
"Automotive" means that such a person is specialized in cars.
SAW welding is a type of arc welding while ERW welding is spot or seam welding. SAW stand for submerged arc welding while ERW stands for electric resistance welding.
There's some information on welding at http://www.WeldingFun.com .. should have the answer your looking for. Sorry for being to lazy to look it up
The main difference between these two types of welding is that GTAW uses gases to create the weld whilst SMAW uses an an electrical current. Both are very popular welding processes.
If by gas welding you mean-oxyacetylene welding. The difference is just that arc welding requires a darker shade of lens. When oxyfuel gas welding (OFW) usually a shade 5 lens is recommended. When arc welding, a minimum of shade 10 lens should be used (actually shade should be determined by amount of current used).
Oxidation can negatively impact the quality of welding by weakening the bond between the metals being joined. This can lead to a weaker and less durable weld, as well as potential defects and imperfections in the final product. It is important to prevent oxidation during the welding process to ensure a strong and reliable bond between the metals.
You can find pretty much all welding defects in Mig welding. There are some that are morelikely to appear than others but that is depending on the gas and power range that is being applied. The defects are: porosity, incomplete penetration (mostly in case of short circuit transfer) undercut, excessive concavity/convexity (incorrect amperage/voltage ratio), cracks (cold and hot) incomplete fusion (wrong torch angles), cold lap.