Burrs are regarded as one of the critical headaches of laser cutting irrespective of the industry, be it manufacturing automotive parts, mechanical equipment, electronic components, or precision hardware. Most technicians seek ways to reduce imperfections, such as burrs.
However, the great news is these imperfections can be avoided with the right combination and handling. Although there isn’t a single solution for burrs, operators can use various methods to reduce burrs in laser cutting, resulting in high-quality clean cuts while saving time, effort, and resources.
Laser-cutting metal workpieces sometimes leave imperfections such as ridges or protrusions, commonly referred to as “burrs.” These imperfections usually emerge as the cutting tool enters or exits the metal sheet.
Almost every technician, irrespective of the industry, comes across this phenomenon, resulting in additional work. Many factors, including the machining method, materials involved, and the operator’s skill level, contribute to such material deformation.
Here are some common types of burr and how they are formed:
When a piece of material falls during the cutting process, resulting in a tear that leaves behind a cut-off burr.
When the cutting tool is applied to the workpiece, the downward tension causes its sides to bulge, bend, twist, or elongate, leaving a Poisson Burr on the edge of the workpiece.
Also known as an Exit Burr, a Rollover Burr, as the name suggests, occurs as the tool is lifted from the workpiece at the end of the cutting.
Metal sheets sometimes give away during the cutting process, with chips of material tearing loose, forming a Tear Burr.
The laser cutting beam generates exceptionally high energy, sometimes bringing the metal workpiece to its melting temperature. Molten metal sometimes solidifies on the workpiece before the assist gas removes them, creating Thermal Burrs.
The forming of burrs is a common phenomenon faced by technicians in various industries. Since burrs require additional work in deburring workpieces, consuming extra time, effort, and resources, burr-free cutting is always desirable. Here are some reasons operators and businesses need to ensure burr-free laser cutting.
Laser cutting is critical in manufacturing various components and accessories in highly competitive industries such as automobiles, electronics, and hardware. Since burrs lower the quality of workpieces, creating burr-free laser cuts is essential to stay ahead of the competition.
Laser-cutting is usually a part of a more extensive process in manufacturing factories. Deburring to correct burrs often creates delays and disruptions to the flow of such operations. Therefore, burr-free laser cutting can enhance manufacturing processes by eliminating the need for burr-related correctional work.
Modern businesses are faced with high operational costs. Burrs usually require additional work and consume unnecessary time, labor, power, and other resources. Burr-free laser cutting avoids such extra work and reduces operational costs, enabling businesses to thrive.
Burrs lead to decreased dimensional, position, shape accuracy, and surface roughness, sometimes failing to meet the specifications. Burr-free cutting ensures the accuracy of workpieces while adhering to engineering drawings and specs.
Burrs lower the surface quality of workpieces. They can also interfere with the fitting or movement of components, making them more susceptible to fatigue and reducing their lifespan. Avoiding burrs can significantly enhance the quality of parts and components being manufactured.
The formation of burrs can sometimes put laser operators at risk. Furthermore, burrs that are left on workpieces can be harmful to end-users. Therefore, burr-free laser cutting prevents manufacturing workers and end users from harm.
Various factors contribute to the formation of burrs in laser cutting. Although it might sound like a highly complex process, technicians can effectively reduce burrs by making vital adjustments to their technique and critical elements in the laser cutting process.
The impure gas can sometimes lead to the creation of burrs in laser cutting. The quality of cylinder gas usually drops after two refills. Additionally, using cylinder gas also results in more wastage after repeated refills.
Nitrogen is preferable as a flame-retardant gas instantly oxidizes molten metals, preventing burrs. Adjusting the auxiliary gas pressure to 12 to 15kg is also recommended, enabling nitrogen to blow away molten metals before they solidify into thermal burrs.
Understanding how the equipment, gas, and parameters combine for cutting is critical in laser cutting. These parameters determine how well the laser beam, gas, and workpiece meet and whether or not the cutting process will lead to burrs.
As machines are put to work in busy manufacturing processes, the parameters change fractionally, leading to below-optimal settings, which lead to an increase in imperfections. Machine fatigue also plays a vital role in the formation of burrs, giving operators and supervisors all the more reason to plan work without overworking operators and machines while ensuring timely maintenance of laser-cutting machines.
Slower cutting doesn’t always materialize into burr-free cuts. Some operators wrongly believe that slowing things down while cutting helps reduce burrs. However, it injects unnecessary heat into the kerf, raising the temperature to extreme levels and disrupting the gas flow due to vaporization.
These disruptions often result in the gas flow being ineffective in evacuating molten metal, leading to imperfections such as burrs. Therefore, operators need to find the sweet spot in the feed rate. Cutting a little faster while ensuring the accuracy of the cut is consequently advisable so that the gas flow properly removes molten material before it solidifies into burrs.
Then there is the other side of the same coin. Laser-cutting technicians are sometimes required to work against the clock to meet hectic targets, resulting in them trying to perform cuts too fast. Doing so not only puts them at risk of injuries but also increases the likelihood of imperfections such as burrs. Therefore, operators need to understand the importance of using the optimal speed to produce burr-free laser cuts.
Burrs are imperfections that form during the laser cutting process, resulting in the need for deburring, leading to wasting time, labor, and other resources. If left uncorrected, burrs affect the precision and quality of the workpieces and components used to produce. Although the common occurrence of burrs makes it seem like a natural part of laser cutting, there are many steps operators can take to reduce burrs significantly.
Using auxiliary gas with fewer impurities, adjusting laser-cutting machines to optimal parameters through routine maintenance, and fine-tuning the cutting techniques of operators are some key methods for burr-free laser cutting, enabling technicians to up their game and produce more precise, smoother, and safer workpieces and components efficiently.
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