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Laser drilling is the process whereby thru-holes are created in a material by pulsing a focused laser repeatedly to break it down layer by layer. Each of the laser processes, whether it is laser marking (FAQs), engraving (FAQs), cutting (FAQs), drilling (FAQs), additive manufacturing (FAQs), welding (FAQs), cleaning (FAQs), ablation (FAQs) or another one entirely, has its own unique qualities and functions. Below we have explored in greater detail some of the most frequently explored laser drilling FAQs.
Laser drilling, as explained briefly above, is the process of using a precision laser to create “popped holes” in a material. The beam intensity, length, and heat output can be precisely and accurately controlled throughout the process, allowing laser drilling to work with a number of different materials and create holes of several diameters and sizes.
This level of control makes it a great alternative to other drilling processes such as mechanical drilling, wire EDM, or punching. Laser drilling is an extremely quick and efficient process, and can be automated to produce the required results, resulting in minimal input needed from employees. Laser drilling is sometimes also referred to as ‘ablation’, as it involves the melting or vaporisation of the material that it is working with. This, in turn, then increases the material volume within the hole that is being laser drilled, resulting in high vapour pressure. This pressure then drives the excess melt out of the hole.
Due to the high level of adaptability that laser drilling offers with beam intensity, duration, and heat output, it is able to work with a wide range of materials. The materials that laser drilling can work with are various metals such as stainless steel, nickel alloys, copper alloys, titanium alloys, aluminium alloys, and brass. Alongside metal, laser drilling is also extremely effective in working with semi-conductors, plastics, quartz substances, ceramics, rubber, and even diamonds.
Laser drilling can be used on many materials, including diamonds
As with the above point, laser drilling’s adaptability means that it is useful in many different industries and sectors. These sectors include; the automotive industry, the aerospace industry, the semi-conductor industry, the electronics industry and the medical sector. Laser drilling is becoming an increasingly vital element of manufacturing processes, and will most likely have been used in many of the everyday products that we use.
Laser drilling offers a number of benefits to its users over other more conventional forms of laser processes. The benefits that laser drilling offers are:
Above lists the wide range of benefits that laser drilling offers, and so it is easy to see why it is quickly becoming a vital part of the manufacturing process. It results in more productive processes, and higher quality end-products.
Laser drilling offers a process that uses a very focused, narrow laser beam that gives precise and accurate results. Thanks to this precise nature, laser drilling is able to result in holes being drilled at incredibly small yet perfect sizes. Before laser drilling, a conventional drill could only create a hole around 0.003” in diameter, which is around the size of a human hair. Now, thanks to the accurate nature of laser drilling, holes with a diameter as small as 0.0004” can be drilled.
Laser drilling finds uses in many industries, including in the automotive industry
As listed above, laser drilling is able to drill holes as small as 0.0004” at incredible speeds. For example, laser drilling is used within the medical sector to drill roughly 140,000 tablets every hour in some instances! Laser drilling can typically produce between 0.3 and 3 holes per second. Laser drilling is capable of incredible accuracy, high speeds, good efficiency, and is very adaptable, allowing it to be worked with a range of materials from metals to rubber to diamonds. A single laser drilling machine is capable of producing hundreds of differently sized and shaped holes over 3D surfaces.
No, this is one of the biggest benefits of laser drilling. It is a non-contact process, and with a precision beam it is only focused on the specific area being worked with. It won’t damage or alter the rest of the material, maintaining the high level of quality that you have started with.
There are several types of laser drilling processes, listed here and below.
Single-pulse laser drilling is when holes are laser drilled through a material with a thin thickness, or just for creating small holes, i.e. when roughing up a surface for coating and gluing purposes.
Percussion laser drilling is similar to single-pulse laser drilling, but is when the size of the laser’s focus spot is changed in order to change the size of the finished hole. Our Fiber Laser range has a laser drilling peak power of up to 20kW, and can drill holes as small as 25µm in diameter and up to a size of 1000µm, although the majority of holes laser drilled using this method are in the 300µm to 600µm range. Percussion drilling involves a series of laser pulses of small energy and duration.
Trepan laser drilling is where a laser pierces a material and then, using a motion system, the laser is used to cut out a hole. This unique method allows for the creation of shaped holes, for a changing cross section, and for the trimming of complex 3D parts and objects.
Helical laser drilling is the process that is used to create large, deep drill holes. The hole isn’t created straight away, and instead several pulses of laser drilling are required to create a circular track in the material being worked with.
Other types of laser drilling include the roughening of surfaces rather than creating thru-holes, and this is typically used for coating and gluing purposes.
Our range of Pulsed Fiber Lasers and Continuous Wave Fiber Lasers are some of the most modern and innovative pieces of laser equipment on the market, and are capable of performing laser drilling to an extremely high and efficient level.
As well as laser drilling, our range of Fiber Lasers also have uses for laser marking, cutting, welding, engraving, ablation, cleaning, and additive manufacturing. If you’re interested in hearing more on our range of Fiber Lasers may be able to benefit you, then please don’t hesitate to get in contact with us.
Image credits: US Air Force, gr8effect, and Gratisography
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