Laser technology offers a wide range of possibilities, ranging from harmless laser pointers to extremely powerful laser marking and cleaning systems.
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Some lasers are powerful enough to damage your skin, cause serious eye injuries, and set your workplace on fire. This is why governmental and international organizations have put in place strict standards separating laser systems into safety classes based on their hazard risks.
Before we go on, what’s a laser?
The term was coined in by Gordon Gould, an American physicist, and the word itself is an acronym for “light amplification by stimulated emission of radiation.” Through optical amplification, laser systems produce highly concentrated light beams that are rich in energy.
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In this article, we’ll go over the different laser standards and laser hazards. But first, what are the different laser classes? And what distinguishes one class from another?
For simplicity’s sake, we’ll focus on the revised laser classification system specified in the IEC -1 international standard. In the United States, ANSI Z136.1 (the old system) is still used and is very similar.
Class-1 lasers are safe for the eyes in all operations even for a long time and with optical instruments. These lasers usually possess a very low output power (a few microwatts).
Industrial lasers of higher classes (such as class 3 or 4) are often converted to class 1 by safely enclosing them (this is called an embedded laser). For example, laser printers use class 4 lasers enclosed in the printer. Therefore, they’re considered class 1 lasers and you don’t need to take precautions during normal operations as long as they’re not damaged.
Examples of class 1 laser solutions:
Class 1M lasers (or, class 1 “magnified”) are much like class 1 lasers since they’re generally safe for viewing with the naked eye.
So what differentiates them from class 1 lasers?
Viewing their magnified beam with optical instruments like binoculars may be hazardous (excluding prescription glasses). Because the beam is amplified, it exceeds the maximum permissible exposure (which is the maximum power density considered safe for viewing).
Laser diodes, fiber communication systems, and laser speed meters are class 1M lasers.
Class 2 lasers can only cause eye injuries if you intentionally stare at them. The blink reflex normally prevents viewing dangerous (and visible) beams for longer than 0.25 seconds. As long as you’re not fighting your instincts, the laser beam is safe for viewing.
Lasers can only be classified as class 2 if their laser light is visible. This is important because the blink reflex as well as other aversion responses (like head movements) won’t be triggered otherwise.
Class 2 lasers are typically limited to 1 mW for continuous-wave lasers (but it could be more in certain contexts). In the old classification system, class IIa lasers are a subclass of class II that is only harmful if the exposure duration exceeds seconds.
Class 2M lasers are generally safe. As with class 2 lasers, the blink reflex and aversion response will protect your eyes from unmagnified beams. But if you view the beam using an optical instrument (even accidentally), the blink reflex won’t be enough to prevent eye hazards. Even the shortest exposure time can be harmful.
Class 3R lasers like laser pointers and laser scanners pose a higher safety risk than previous classes, but they’re still considered safe when handled carefully. Eye injuries may occur if you directly view the beam—especially when using optical instruments. But generally speaking, a brief eye exposure won’t harm your eyes (the acceptable exposure time varies according to the wavelength).
Since exposure to the beam is low risk but potentially hazardous, class 3R lasers must be identified with appropriate warning labels (this is also true with higher laser classes). If you’re using the old classification system, you’ll find that class IIIa lasers (or class 3a) are essentially the same.
Direct contact with the laser beam or specular reflections (also known as mirror-like reflections) of 3B lasers must be avoided. They may cause eye injuries or small burns on the skin.
Only diffuse reflections are safe with class 3B lasers.
To get an idea of the maximum emissions permitted for class 3B lasers, take a look at the following accessible emission limits (AEL):
Entertainment light shows fall into this category. If you’re using the old classification system, class 3B is the same as class IIIb.
Class 4 lasers are the most dangerous. Proceed with extreme caution if the laser is not properly enclosed.
The output power of class 4 lasers is so high that they can ignite materials. That power is what makes them attractive for laser cutting, laser marking, laser welding, and laser cleaning.
Class 4 is the highest class in terms of laser hazards. If you’re within the hazard zone, you’re exposed to severe eye and skin injuries. In addition, combustible materials shouldn’t be in the laser’s surroundings to avoid fire hazards.
Diffuse reflections of class 4 lasers are also hazardous. You could get sunburns or lose sight simply by looking at a workpiece being processed.
A good rule of thumb is to pay attention to warning labels, wear protective equipment, and follow any additional control measures for laser safety.
Fortunately, class 4 lasers can be properly enclosed to render them essentially harmless. For example, automated laser marking machines manufactured by Laserax are class 1 laser products, but they include high-power, class 4 laser systems that range from 20 watts to 500 watts.
Now that you have a good idea of the degree of danger of each laser class, let’s look at the types of dangers.
Laser radiation can cause three basic types of laser hazards: eye, skin and fire hazards.
If a laser is not class 1 compliant, workers should wear protective equipment when entering the danger zone: laser safety glasses for eye protection and special suits for skin protection.
Of all the laser hazards, eye injuries are the most serious. Losing sight is no small thing. Let’s explore why eye injuries occur and how you can prevent them.
When light reaches the eye, the cornea and the lens act as amplifiers. Like a magnifying glass, they concentrate light onto the retina (the back of the eye) which, afterward, is processed by the brain as an image. Those three components of the human eye (cornea, lens and retina) are the most susceptible to damage from laser radiation.
Almost all types of laser lights can harm your eyes, but the various components of the human eye react more strongly with some light wavelengths. Most laser engraving machines produce light in the near-infrared (700- nm) and the far infrared ( nm - 11,000+ nm) spectrum—all of which are invisible to the human eye.
Part of visible light is absorbed by the eyes before being amplified by the lens and cornea. This protects you by reducing the output power of light.
But infrared light isn’t visible and isn’t absorbed by the eyes. When invisible light reaches the retina, it’s more powerful and more dangerous than visible light.
All this energy is spent burning a small area of the retina which causes blindness and severe eye damages. Photochemical damage is also possible for lights lower than 400 nm (in the ultraviolet range) and may cause cataracts (decreased vision).
Protective eyewear like laser goggles protects you by absorbing dangerous light. Different goggles absorb different lights, so you need to wear the right goggles for your laser class. For example, you need goggles that protect you against the nm wavelength for the Laserax fiber laser systems.
If you had the choice between putting your eyes or your hands on the stove, chances are you would put your hands. With this in mind, it’s easy to understand why skin hazards are less serious than eye hazards. But the risks of skin burns still deserve attention.
Direct contact with the laser beam and specular (mirror-like) reflections can cause skin injuries. Those injuries are typically caused by thermal damage similar to touching the stove, or photochemical damage like sunburns.
The burn level depends on the laser’s output power, the wavelength, the size of the affected area, and the duration of the irradiation.
Apart from health hazards, laser light can also start fires and put your work environment at risk.
Only class 4 lasers pose real fire safety concerns. Their direct beam as well as any type of reflection can ignite combustible materials. For a safe integration, those lasers must be enclosed properly and account for all possible angles of reflection, including diffuse reflections.
Laser standards were first put in place when scientists recognized that even low-power lasers could be potentially dangerous. They provide appropriate laser safety measures to prevent health and fire hazards.
All standards explain the different classes, how to calculate certain laser parameters, the proper labels, safety measures when handling the laser, and so on. They also enforce safety measures like the nominal hazard zone, which defines where direct laser light, specular reflections and diffuse reflections are dangerous.
Laser standard resources:
When you buy laser solutions and systems, you should either get a class 1 laser machine or work with integrators who make sure your class 4 laser system is class 1 compliant.
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Here at Laserax, laser experts offer guidance to make sure all products are 100% laser-safe, including laser fume extraction.
Based on their possible risks to people and the environment, lasers are divided into 4 major categories. These laser classes contribute to the safe application of laser technology. The laser's power output, potential fire hazards, and threats to the skin and eyes are the basis for the classification system.
1. Class 1 (Completely Safe)
2. Class 2 (Low Power, Eye Hazard if Stared Into)
3. Class 3 (Moderate to High Risk to Eyes and Skin)
4. Class 4 (High Power, Serious Hazards)
MPE stands for Maximum Permissible Exposure. It refers to the highest level of laser radiation to which a person may be exposed without hazardous effects on their health, particularly on the eyes and skin.
MPE values are established by safety standards like the American National Standards, ANSI Z136.1 (for the U.S.) and IEC -1 (international).
AEL stands for Accessible Emission Limit. According to international and American national standards, it is the highest amount of laser radiation that a system can produce without going above the radiation safety criteria for its assigned laser class.
An AEL determines the class of laser and is calculated based on the MPE while considering real-world operating conditions such as beam divergence and distance from the source.
If you want to discuss laser safety and your application, contact us to discuss with an expert.
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A laser beam is used in the process of laser welding to join together two pieces of metal without actually touching them. This method allows for the production of welds that are both thin and have a low level of thermal distortion. Due to its speed, ability to control the welding quality during the operation, and high level of automation, laser welding is used extensively in a variety of industries, including the clinical, electronic parts, tool making, and automotive sectors, amongst others.
There are several reasons to choose a laser welding machine:
The laser allows for extremely rapid heating of the metal while minimizing the risk of deformation. Because this technology is particularly effective for welding large amounts of sheet metal, it is widely used in the automotive industry.
Allowing for localized, very fine, very clean, almost invisible welding. They are especially well-suited for welding small parts. Because it provides the most aesthetically pleasing welding, this type of welding is very popular in the dental and jewelry industries. It is also possible to split the laser beam into several beams to provide more accurate welding.
Metals, including refractory metals, are the primary material for which laser welding machines are used. They can also be used to successfully weld materials that aren't metal, like ceramics and glass. They are useful for joining together pieces of widely varying shapes and sizes.
With a laser welding machine, there is no physical contact between the two pieces being welded, so the equipment is protected from unnecessary wear and tear. The elimination of tool and electrode changes is an additional bonus that helps cut down on waste.
Weld quality can now be monitored and adjusted in real time by a computer, which greatly improves productivity. Such a process allows for a great deal of automation, which in turn allows for the identification and correction of any quality issues that may arise.
However, it is important to note, that laser welding machines do have some drawbacks.
Laser welding machine has advantages over other methods. With laser welding, a 'keyhole' can be created, which has many benefits. This keyhole allows heat input through the material's thickness (s). Advantages include:
Fast laser welding. Thin-section materials can be welded at many meters per minute, depending on the laser type and power. Lasers excel in high-productivity automated environments. For thicker sections, laser keyhole welding can complete a joint in a single pass, whereas other techniques require multiple passes. Laser welding is almost always automated, with optical fiber delivered beams from Nd:YAG, diode, fiber, and disc lasers being easily remotely manipulated using multi-axis robotic delivery systems, resulting in a geometrically flexible manufacturing process.
Laser welding creates high-aspect-ratio welds (large depth to narrow width). Laser welding is suitable for joint configurations unsuitable for other (conduction-limited) welding techniques, such as stake welding through lap joints. This allows smaller flanges than resistance spot-welded parts.
Lasers create keyholes with concentrated heat. Laser welding produces a small volume of weld metal and transmits little heat into the surrounding material, so samples distort less than with other methods. Low heat input also narrows the heat affected zones on either side of the weld, resulting in less thermal damage and property loss in the parent material.
Steels, stainless steels, and Ni alloys, plastics, and textiles can be welded or joined with lasers. Depending on the type and power of laser, steels can be welded from under a millimeter to 30mm thick.
Laser welding is done at atmospheric pressure, unlike electron beam keyhole welding, but gas shielding is often needed to prevent weld oxidation.
Laser welding does not apply force to the workpieces being joined and is usually a single-sided process. Weld root shielding from the opposite side may be required, as with other fusion processes.
Lasers can make spot or stitch welds as easily as continuous welds, if suitable.
With a few adjustments, a laser source can also be used for cutting, surfacing, heat treatment, marking, and rapid prototyping. The beam(s) can be delivered to the workpieces in several ways, including: One laser source can process multiple jobs by sharing a beam between welding stations. One laser source can process two areas (or the same area from opposite sides) on a workpiece by energy-sharing a single beam. Special transmission or focusing optics shape or split beams to process materials with different energy distributions.
You have a choice between using a pulsed laser or a continuous laser in your laser welding machine. What determines which one is better to use is the thickness of the material being welded.
Pulsed laser.
It works well with lightweight, thin metals. They won't melt or become deformed thanks to this. Pulsed lasers like these are typically employed for welding sheet metal, razor blades, gold jewelry chain links, and titanium pacemakers.
This is the laser that never stops shining.
When welding thick materials, this method is highly recommended. If you have any recalcitrant metals, you should try this method. Using it on metal or a too-thin component can cause issues. The laser risks damaging, deforming, or melting the component under these conditions. Compared to a pulsed laser, it is more expensive, but it saves money in the long run.
Fiber lasers, CO2 lasers, and Nd: YAG lasers are the three primary options. Depending on the laser system you've decided to go with, different options will be available (pulsed or continuous).
Because of the sharpness and thinness of the beams used in this technology, work can be done in a continuous and penetrating fashion. The fiber laser, like the CO2 laser, can quickly and efficiently cut through thick sheets. In contrast to other types of lasers, it is simpler to use and maintain when it is built into a machine. Typically, this laser operates at a 25% efficiency rate.
With this method, a gaseous combination of carbon dioxide, helium, and nitrogen is electrically excited to achieve optimal performance in a nonstop setting. CO2 lasers, similar to fiber lasers, can quickly and efficiently cut through thick sheets. It is more popular than the fiber laser because it can more easily cut through thick steel. When compared to the fiber laser, this one is more versatile and capable of cutting through both thicker and thinner materials with ease. An average efficiency of 7% for 8,000 W is provided by this laser.
All aspects of laser pulses, including intensity, duration, and profile, can be precisely managed in this way. Pulsed mode is its natural habitat. But the pulses it sends out have such a wide range of wavelengths that not all of them hit their mark and instead dissipate into heat. This laser's efficiency ranges from 3-4%, significantly lower than that of CO2 lasers (7-10%) and fiber lasers (25-30%).
It is important to double check a few things before firing up your laser welding machine. In order to ensure that your welding operations go smoothly, here are some standard safety measures to take.
Higher pulse frequencies lead to lower pulse energies, which in turn leads to subpar or nonexistent welding performance.
In order to get the best results when welding different metals, we suggest switching the waveform. Depending on the waveform chosen, anywhere from 60 percent to 98 percent of the laser's energy will be wasted, rendering the welding operation useless.
Welding machines can be set up in one of three ways:
The following factors will determine which configuration is selected:
There are 4 different types ofbest laser welding machines available. Check out our extensive selection:
Continuous lasers are the way to go when you need to weld thick materials. It works wonders on hard-to-melt metals. Use on metal or on an overly thin component can cause issues. Although it's more expensive than a pulsed laser, it saves money in the long run.
In laser welding, a highly concentrated beam of light is used as the heat source, and a lens is used to achieve this high directivity and convergence. By controlling the intensity of the laser beam, it is possible to perform penetration welding with a very small weld bead.
Therefore, the types of lasers used for laser welding can be generally divided into gas lasers or solid-state lasers.
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