The current industrial regulations require parts to have clearly legible identifications, therefore, increasing the popularity of the laser marking process. Previous industrial trends required manufacturers to mark surfaces with traditional engraving or screen printing processes. These processes were non-permanent, costly, and usually caused part defects.
However, the introduction of laser marking now allows engineers and manufacturers to create numbers, images, or characters without compromising part quality. Instead of using physical tools for etching surfaces, this technique employs focused laser beams to create easy-to-read, damage-free marks.
Laser marking is a very versatile process, encompassing different techniques such as engraving, etching, foaming, carbon migration, etc. The right marking method will depend on your material and quality requirements. Read on as we discuss the details of this innovative technique.
Laser marking is a process that uses a concentrated beam of light to create permanent marks on the surfaces of target components. The process is typically carried out with a laser machine using an oscillator, a scanning mirror, and a focusing lens.
The machine also allows automation and processing at high speeds, consequently leaving permanent traceable marks on a wide range of materials. Laser marking allows parts and products to be marked with:
The laser marking technology creates lasting marks on component surfaces by generating focused beams of light containing high energy levels. The built-up energy is released in the coherent light beam directed at the material surface using mirrors.
As a result of the light beam interacting with the components surface, there is a transfer of heat energy from the beam to the surface. Therefore, the appearance and properties of the material will change. Depending on the energy level, the laser can engrave, etch, anneal, or discolor surfaces with great precision.
The concentrated beam targets only specific areas on the material, ensuring precise, high-contrast, and high-quality marks. These marks are permanent, and you can easily read or scan them on any surface. As a result, this marking process is ideal for operations where permanency and accuracy are critical.
Laser technology began with Albert Einstein back in the early s, and further evolution was seen in with the creation of the first CO2 laser. Peter Houldcroft of The Welding Institute (TWI), Cambridge, pioneered the first commercial applications of Laser Material Processing. The earliest Laser Machining applications were driven by manufacturers of automobiles and aircraft components.
In a bid to improve computer engravings, Electrox developed the first commercial axial flow CO2 laser machine as a major source of laser marking systems. Technological advancements in the s and s led to an integration of computer systems into laser marking. The more efficient and modern fiber lasers came to light in , and has improved ever since.
Today, laser markers are more improved, accurate, faster, and more environmentally friendly. There are now more versatile and cost-effective laser marking technologies, creating high-quality durable markings directly on parts surfaces. These technologies are faster, more compact, and can create marks on a wider range of substrates.
As a result of the more powerful and flexible systems, users can create consistent markings on a large batch of products. Therefore, they achieve business goals within a short time and at lower prices.
There are several laser marking technologies for different applications out there. Each technique has its benefits and downsides, and your choice will depend on budget, quality requirements, and applications. Lets examine some of these techniques.
This process involves the removal of some materials from components surfaces using laser beams. During the process, the material will absorb heat from the laser, melt, and evaporate, creating marks in the form of depressions. The material will also react with air, causing a color change to make the mark more distinctive.
There are no consumables involved in laser engraving. Thus, it attracts low operational costs compared to other engraving methods that use special inks or drill bits. Laser is suited for a wide range of materials, including metals, plastics, and ceramics. Therefore, engineers employ it for many diverse applications.
This highly versatile process creates marks on workpieces by melting their surfaces. The laser beam produces a raised mark by delivering high amounts of energy to a small, localized area. Consequently, the surface will melt and expand, changing the color to black, gray, or white.
Etching is commonly used for producing permanent markings like serial numbers, data matrix codes, logos, and barcodes. It is also a versatile process ideal for a wide range of metals, including aluminum, lead, steel, magnesium, stainless steel, etc.
Related: Understanding Differences Between Laser Engraving and Laser Etching.
In laser annealing, the laser beam will heat the material surface locally to create the mark. The beam only penetrates between 20 to 30 µm into the material surface, thereby resulting in a very minimal change on the surface. The localized heating causes color changes in the material. The marking could be black, red, yellow, or green, depending on the temperature of the heated layer.
The results of laser annealing are permanent abrasion-proof markings. Laser annealing works best on ferrous metals and titanium. Therefore, various industries can use it, ranging from healthcare to automotive, food and beverages, and aerospace industries.
In this method, heat energy from the laser will break plastic bonds and release oxygen and hydrogen. This reaction causes the target area to darken, giving a grey to blue-gray mark. Carbonizing or carbon migration is always the ideal option for marking synthetic polymers and organic materials.
It works well with paper, wood, leather, packaging materials, etc. However, carbon migration is not very suitable for dark-colored objects. The grey mark formed will have lower contrast to the rest of the workpiece, making it difficult to read the markings.
While carbon migration may not be of much help when you need to produce light-colored markings, foaming is more suitable for these kinds of applications. The process involves heating the material surface with the laser, causing it to melt and emit gas bubbles. When the gas bubbles oxidize, they form a sort of frothing, causing them to reflect light.
This method is one of the best marking options for dark-colored components. This is because the mark is raised above the components surface with higher contrast with the other parts of the surface. It is also ideal for marking polymers.
In this technique, the laser removes layers of the workpiece, revealing the underneath layer. The removable material absorbs heat from the laser and vaporizes to produce a contrast. Therefore, it is crucial to ensure that the color of the top coat is different from that of the base material.
This method is more effective for coated materials like anodized aluminum because they will display excellent and legible markings. Other materials that work well with discoloration are laminates, films, and foils. It is an excellent technique for marking labels, fittings, and packaging objects.
There are many types of laser marking machines you can use for different applications. Each of these laser markers is ideal for different materials and operations. Here, we will discuss the two most common laser markers. So, read on to know which one to choose between fiber laser vs. CO2 laser.
These laser markers are often sealed-tube marking systems with galvo-steered light beams designed to mark non-metal surfaces. CO2 laser markers are popular options for product recognition markings, logos, date stampings, and many more. These machines help create serial numbers, logos, and barcodes on electrical appliances, integrated circuits, food & medical packaging, and electronic components.
The wavelength of sealed-off CO2 lasers gives the best marking results with organic materials like papers, wood, and some plastic polymers. They are also suitable for leather and glass markings.
This laser marking machine is suitable for coated metals like painted brass and coated aluminum. There is no need for any pre-treatment with CO2 laser marking. The fact that you can use it for various non-metals makes it a versatile process for many industries, from electronic to medical and packaging industries.
However, getting a CO2 laser machine that supplies big power can be quite expensive. Furthermore, energy consumption and operation requirements with this type of laser marker are high, increasing overall costs incurred.
The popularity of this laser marking technology has grown in recent times because these laser markers are among the most powerful available today. These solid-state lasers have power levels ranging from 20 to 50 watts, stimulating the production of ytterbium, a rare-earth metal. This metal element generates photons of about 1,090 nm wavelength, which is ideal for marking metal materials.
The fiber laser marking machine is suitable for depth engraving or etching. They offer greater results on harder metals or when you need a high-powered system with smaller spot sizes to get higher resolution. As a result of the small spot sizes, high beam quality, and larger lenses, these markers are ideal for small-component batch markings.
The fiber laser setup is highly versatile and creates marks more effectively at faster marking speeds. This laser marking technology also boasts zero consumable requirements, economic power usage, and minimal maintenance, making it more affordable than CO2 lasers.
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The high level of monochromatic beam filtration ensures you get varying powers of one type of beam. Therefore, you can use fiber lasers on many kinds of surfaces. Varying the wattage on these laser markers allows you to archive various engraving depths based on your components applications.
However, it may not work fast on very thick materials with high reflection properties. It may also not be able to create deeper engravings on most metals.
Besides the common laser markers discussed above, there are other laser marking machines that deliver great results. They include:
Green lasers operate in the green visible light spectrum (532 nm) with power ranging from 5 to 10 watts. They are designed to create marks on highly reflective materials. In addition, they exhibit high precision and excellent work ease, making them ideal for sensitive substrates such as silicon wafers. These lasers display greater absorption for different materials and mitigated thermal energy. Therefore, they are excellent for soft plastics, circuit chips, PCB boards, etc.
UV lasers are designed with a highly absorptive wavelength of 355 nm for part marking. As a result of their high absorption rate, they are perfect for cold marking, ensuring there are no heat stresses on the material. UV lasers can mark several surfaces such as plastics, glass, and ceramics. The high-quality beam can also micro-mark electronic materials and medical equipment with precise marking.
These types of laser markers are compact and lightweight. They are popular due to their unique ability to mark thin sheets of metal without causing warpage or distortions. As a result, manufacturers use it for small markings on several substrates such as aluminum, steel, and other plated metals.
The advances in marketing techniques have opened the eyes of project managers to the need to brand their products. As a result, laser marking is now an essential part of manufacturing processes, helping businesses track their products, minimize counterfeiting, improve quality, and more. It helps you make precise markings with high precision, saving you time and money.
To help you understand the great potential of this marking technology, here are some benefits to keep in mind:
Laser marking combines laser technology with computer technology, ensuring faster implementation and time-saving. This technique allows you to create designs on a computer and use the latest graphic design technology.
Conventional marking methods use specific tools that make the processing time-consuming. On the other hand, laser marking machines only need a command to get the job done within a short period. This is the perfect option for shortening a products development cycle, speeding up your processes, and saving you lots of money.
Marking processes like chemical etching and inkjet use chemicals and inks for marking. These consumables are often expensive and release harmful fumes to the environment, which can have negative effects. However, laser marking does not make use of any consumables. Therefore, it is a clean, energy-efficient, and environmentally friendly process.
Likewise, this marking technique is a non-contact process, ensuring clean processing and limiting material contamination. While other printing systems may burn the material down, laser marking is damage-free, involving little to no material penetration.
There are various laser marking machines, and each marker can work on a wide variety of materials. For instance, CO2 lasers give the best marking results with organic materials like papers, wood, and some plastic polymers.
Likewise, fiber lasers and Nd:YAG lasers can work with various metal grades, including steel, aluminum alloys, stainless steel, etc. UV lasers can mark surfaces such as plastics, glass, and ceramics.
Laser markers can successfully mark a larger product batch with a specific design within a mass manufacturing setup. This marking technique makes it easy to integrate identical markings into a production line. Furthermore, the repeatability is consistent, allowing faster turnaround times and aesthetically-pleasing products.
Marks created by lasers are usually permanent with high contrast properties. These water-resistant and fade-proof marks can withstand abrasion, heat, and acids. Therefore, laser markings are the best choices for durable marking needed for reliable product tracing, and you wont have to fear the mark fading off.
Laser marking is a no-contact technique. Thus, there is no mechanical wear between the laser marking system and the workpiece. This ensures that maintenance and downtime are kept to a minimum. You also need low maintenance to remove any accumulated dust from the mirrors used.
The possible use-cases of laser markings continue to increase, thanks to the ever-developing technology. Therefore, laser marking processes now find applications in an extensive range of industries.
Many industrial and commercial products require labeling. These products include machine tools, integrated circuits, keyboard buttons, food packings, medical equipment, printed circuit boards, and many more. Laser marking helps create these labels, including model and serial numbers, QR codes, bar codes, part numbers, logos, dates, etc.
Traceable information is often required for quality control. Laser marking also helps to create permanent identification markers on various components. Examples include silicon wafers for photovoltaic cells, indications on electronics, smart cards on automotive parts, and more. This way, you can easily trace back and solve possible problems quickly.
Knowing the applications of laser marking is enough; you need to work with a reliable manufacturing partner who offers high-quality laser marking services. If you have parts requiring laser marking, you should work with RapidDirect. Our expert technicians are skilled and experienced in laser marking technologies, and you can be sure of the best results.
RapidDirect also provides manufacturing services, including CNC machining services, sheet metal fabrication, injection molding, and 3D printing. You can upload your design file on our online quotation platform to get an instant quote and a free DFM report. Our skills and state-of-the-art technology ensure fast lead time at competitive prices.
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Laser marking is a versatile process encompassing an extensive range of technologies to produce precise, permanent, and high-quality marks. This eco-friendly process is an excellent alternative to traditional marking techniques, ensuring high production speed, consistent repeatability, the durability of marks, and low maintenance. Therefore, it is an excellent choice for your applications.
Whenever you need high-quality laser marking services for your products, contact RapidDirect, and lets help you get started!
Understanding how the laser marking process works is only possible by understanding a laser marking machine and its generation of the laser beam responsible for the marking.
The generation of the laser beam in any laser marking equipment depends on three important components:
The lasing medium is responsible for the wave position and the excitation energy required by the machine. Common lasing mediums include neodymium-doped yttrium aluminum garnet (solid) and organic dyes (liquid), and CO2 (gas). The lasing medium can also be a geometric shape, such as the fiber lasers.
The pump source is responsible for introducing energy to the laser marking machine, which excites the lasing medium and leads to photons emission through spontaneous or stimulated emission.
The optical resonator has a reflective (high reflector) and partially reflective (output coupler) mirror. It functions in reflecting the light produced by the lasing medium. It can also contain other things, such as a modulator and q-switch, that can change the generated laser beam properties.
Energy becomes introduced into the lasing medium. This leads to the excitation of the lasing medium atoms and the emission of photons. The light enters the optical resonator and undergoes total internal reflection to create the laser beam. The laser can then be passed to components such as the q-switch, lenses, beam expanders, etc., to shape the beam before releasing it.
When the laser beam touches the workpieces surface, the heat energy produced causes a change in the features and attributes of the material. The types of change depend on the laser technology you choose. A permanent mark is then left on the surface of the workpiece.
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