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Laser Cutting History – a Revolutionary Evolution

Laser Cutting History – a Revolutionary Evolution

Laser cutting is an everyday method for manufacturing your details today. The 4 billion dollar industry is responsible for producing cars, ships, machines, furniture etc. Although it is present everywhere, few of us know the history behind laser cutting. The revolutionary technology has its roots at the beginning of the last century.

Laying the foundation

Laser is an acronym – Light Amplification by Stimulated Emission of Radiation. The shortened form is a necessity because of its mainstream presence. Metal cutting is one of the use-cases that has gained a lot of ground. Although many see it as a new technology, laser cutting history dates back a hundred years.

Of course, it is the genius Albert Einstein, who is behind the idea that makes production faster. In 1917, he laid out the theoretical foundations to make the laser possible in his paper On the Quantum Theory of Radiation.

Other scientists further innovated on Einstein’s ideas. Different advancements in the first half of the century made the contemporary technology possible. In mid-century, development picked up speed.

The first pulsing laser prototype dates back to 1960. Soon afterwards came the first gas laser capable of continuous operation. In the 60s, laser cutting was seen as a solution. The problem to match the solution was still missing. It didn’t take long for people to realize the potential applications in different industries.

This led to the inception of the first production laser cutting machines in 1965. Western Electric, the company responsible for making these machines, used them to cut holes in diamond dies. 50 years after Einstein’s paper, in 1967, gas-jet laser cutting machines were used for cutting 1mm thick metal sheets. The capabilities demonstrated raised the heads of many.

Among the raised heads was the aerospace industry. They started using lasers for cutting materials like titanium and ceramics in the 70s. This was a big step towards the contemporary use-case, as lasers before were mainly able to cut non-metals.

CO2 lasers

The first wide-spread laser cutting method was CO2. It is still the number one technology for good quality cutting.

Laser cutting classifies as a thermal cutting process. The laser device creates the beam and directs it towards the outlet via mirrors. The mirrors form a resonator that builds up the light energy in the beam. On its way, it goes through a focusing lens that concentrates the beam. From there, a nozzle channels it onto the working piece. The amplified beam melts the metal.

Along with the laser beam, gas is emitted. When cutting mild steel, pure oxygen is released to start a burning process. In case of stainless steel or aluminum cutting, the laser beam just melts the metal. The cutting gas is then nitrogen, to blow out the molten metal and keep the cuts clean.

For lasers to work, the material must absorb the emitted heat. With metals, a large portion of the light is reflected back. Therefore, a powerful laser is needed to generate the necessary heat for cutting despite reflection.

The light that bounces back can harm the machine. Some copper-based alloys and types of aluminum are too reflective for CO2 lasers. This is a limitation that hampers different use-cases.

Fiber lasers

The first fiber lasers were introduced in 2008 at EuroBlech. The different laser beam conveying methods allowed cutting highly reflective metals. Now, metals like aluminum, brass, copper and galvanized steel are available for laser cutting.

Fiber lasers are simpler and more durable. The laser light is first created by banks of diodes. It is then channeled through optic cables, where it gets amplified. The cables are doped with rare earth elements like erbium, thulium and the like. These elements are used for amplifying the light. Finally, the lens focuses the light to form a laser beam ready for cutting. The new system needs no gases, mirror realignments nor warming up.

A big advantage of fiber lasers is its high energy conversion rate. Around 75% of the received power is converted into the laser beam. The CO2 laser efficiency is around 20%. The significant difference comes mainly from the low losses in heat generation. This makes 2kW fiber lasers comparable to their 4 kW CO2 counterparts.

The major improvements spur on engineers to continue developing this revolutionary technology. This is an indication for the future.

Future trends

Although the majority of the market is still in the grasp of CO2 lasers, fiber lasers are catching up. Now, an increasingly large share of new sales is reserved for the latter.

The costs and maintenance of fiber lasers is a big selling point. There are fewer moving parts and less adjustment to make. That results in lower down times due to maintenance.

Today, the fiber laser is significantly quicker when cutting thin metals. CO2 still beats fiber when cutting thicker materials (10mm and more) with its better edge quality. Considering the short time on the market, we anticipate more advancements in this field. 

Altogether, the future seems bright to fiber lasers. Manufacturing is a traditional industry where changes take a long time. But fiber has set its eyes on dethroning CO2 as the leader in the industry.

Man vs Machine

Finally something entertaining about Arnold and the Terminator? No. Something about machine operators.

All of the above may lead one to choose a manufacturer based on their machine park. Power availability is an indication of potential capabilities. However, it is not a guarantee for quality.

Although the cutting is automatic, setting it up is not. Machine operators play a big role in ensuring the final quality of your details. The expertise and experience lets them choose the right parameters for each production need.

Therefore, finding suitable manufacturers is still a tedious task. Fractory.co has identified a bunch of trustworthy manufacturers who take good quality seriously. If you need help with sheet metal production, we can provide it.

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