DUBLIN–(BUSINESS WIRE)–The “Global Laser Cutting Machine Market 2019-2023″ report has been added to ResearchAndMarkets.com’s offering.

The laser cutting machines market analysis considers sales from fiber, solid-state, diode, and others. The analysis also considers the sales of laser cutting machine in APAC, Europe, North America, South America, and MEA. In 2018, the fiber segment had a significant market share, and this trend is expected to continue over the forecast period. Factors such as technological advances and growing industrial applications will play a significant role in the fiber segment to maintain its market position.

Also, the market report also looks at factors such as increasing focus on automating the metal cutting process, rising demand for fiber laser cutting machines, growing investment in aerospace and defense industry. However, availability of alternate machine tools for metal cutting applications, decline in sales of automobiles, increasing demand for refurbished laser cutting machines may hamper the growth of the laser cutting machine industry over the forecast period.

The metal cutting process is mechanized, and various steps are being initiated by vendors to produce automated cutting machines. The increasing need to meet market demands for optimized flexibility and personalization in terms of product design and proportions in the cutting process has enabled integration across all production steps. This integration is now prominent among all functions within and outside a company floor.

Individual standalone laser cutting machines can now be integrated into the production flow using automated software; this enables large industrial plants to partially shift toward unmanned production processes, which ensures high performance with a reduction in human resource requirement. This increasing focus on automating metal cutting process will lead to the expansion of the global laser cutting machine market at a CAGR of almost 5% during the forecast period.

Vendors are focusing on developing a connected device and streamlining the complete manufacturing process with the use of industrial internet of things (loT). loT comprises a network of physical objects with an IP address, which allows it to connect to the internet, it also includes communication between these objects and other internet-enabled devices. loT is an internet network that extends beyond conventional devices, such as laptops, desktop computers, and tablets. This development is expected to have a positive impact on the overall market growth.

With the presence of several major players, the global laser cutting machine market is fragmented. The robust vendor analysis is designed to help clients improve their market position, and in line with this, this report provides a detailed analysis of several leading laser cutting machine manufacturers, that include Coherent Inc., Conzzeta Management AG, Han’s Laser Technology Industry Group Co. Ltd., IPG Photonics Corp., and TRUMPF GmbH + Co. KG.

Also, the laser cutting machine market analysis report includes information on upcoming trends and challenges that will influence market growth. This is to help companies strategize and leverage on all forthcoming growth opportunities.

The Global Laser Marking Machine market is expected to reach $4.09 billion by 2026 growing at a CAGR of 7.7% during the forecast period.

Rising demand for the print of everlasting alphanumerical code on the product, growth of the machine tool industry and increasing industrial-technological advancement are some of the factors fuelling the market growth. However, high initial investment and lack of adoption of this technology in underdeveloped regions restrict the market growth.

Laser marking is a laser technology where the laser beam is used for marking/engraving a work piece or other product. It has always been an important factor in industrial activities, especially in automobiles and machine tools as they provide permanent alphanumerical details on the product in terms of brand name, batch number and other details. This engraving helps in identification and security of the products. Laser marking machines are generally of three genres. Main components of these machines are the laser, controller, and a surface. Laser marking technique is normally applied on natural materials (like wood, walnut, etc.), plastics, metals, coated metals and stone/glasses.

Based on end user, Machine tools have considerable growth during the forecast period owing to booming industrial manufacturing & processing sector and high demand of mid to high-end machine tools from marine, automobile, aerospace, and other industries. These machines are also used predominantly in semiconductor & electronics industry for silicon wafers and Printed Circuit Boards (PCBs) marking. By Geography, The Asia Pacific is expected to grow at the significant market share during the forecast period owing to the growth of automobile, machine tool, aviation, electronics, manufacturing, and other end-user industries and rising demand of various marking tools.


The customized machines purchased by American agents are packed and delivered today. Thank you for your trust!



We will attend the media exhibition in New Delhi, India from September 6 to 8. Customers are welcome to visit the booth and visit the machine!



Laser cutting of textiles offers unparalleled advantages over machine or manual cutting. Zero fabric distortion, sealing of cut edges during cutting of synthetic textiles, precise cutting of filigree details, less clearance efforts due to low dust production, uniform processing in all directions irrespective of fabric, and consistently high cutting quality. Collectively, this boosts uptake of laser cutting of textiles.

This is where laser fabric cutting machines come into play. Laser fabric cutting machines are of various types, which vary in terms of performance and supporting units. For example, CO2 laser cutter for textile cutting feature easy exchange of data with external system provider, camera recognition, conveyor system, and less wastage. Resultantly, growth of laser fabric cutting machines market is poised to be bright in future.

The Laser Fabric Cutting Machines market was valued at xx Million US$ in 2018 and is projected to reach xx Million US$ by 2025, at a CAGR of xx% during the forecast period. In this study, 2018 has been considered as the base year and 2019 to 2025 as the forecast period to estimate the market size for Laser Fabric Cutting Machines.

This report presents the worldwide Laser Fabric Cutting Machines market size (value, production and consumption), splits the breakdown (data status 2014-2019 and forecast to 2025), by manufacturers, region, type and application. This study also analyzes the market status, market share, growth rate, future trends, market drivers, opportunities and challenges, risks and entry barriers, sales channels, distributors and Porter’s Five Forces Analysis.

Laser Fabric Cutting Machines Breakdown Data by Type Numerical Control Type Fabric Cutting Machines Automatic Type Fabric Cutting Machines Laser Fabric Cutting Machines Breakdown Data by Application Cloth Cutting Leather Cutting Synthetic Fiber Cutting Cotton Cutting Other

Laser Fabric Cutting Machines Consumption by Region North America United States Canada Mexico Asia-Pacific China India Japan South Korea Australia Indonesia Malaysia Philippines Thailand Vietnam Europe Germany France UK Italy Russia Rest of Europe Central & South America Brazil Rest of South America Middle East & Africa GCC Countries Turkey Egypt South Africa Rest of Middle East & Africa

The study objectives are: To analyze and research the global Laser Fabric Cutting Machines status and future forecastinvolving, production, revenue, consumption, historical and forecast. To present the key Laser Fabric Cutting Machines manufacturers, production, revenue, market share, and recent development. To split the breakdown data by regions, type, manufacturers and applications. To analyze the global and key regions market potential and advantage, opportunity and challenge, restraints and risks. To identify significant trends, drivers, influence factors in global and regions. To analyze competitive developments such as expansions, agreements, new product launches, and acquisitions in the market.



When I got my first 3D printer I was excited, but now that I’m contemplating adding a forth to my collection, I have to come to the terms with the fact that these machines have all the novelty of a screwdriver at this point. Which is fine; getting the cost down and availability up is the key to turning a niche piece of technology into a mainstream tool, and the more people with 3D printers at home or in their workshop the better, as far as I’m concerned. But still, there’s a certain thrill in exploring the cutting edge, and I’ve been looking for something new to get excited about as of late.

Lasers seem like an interesting next step in my quest towards complete in-house fabrication capability, so I started researching cheap setups to get my feet wet. In the course of looking up diode-powered laser cutters, I came across the NEJE DK-8-KZ. At only 1W, there’s no question this device isn’t going to be cutting a whole lot. In fact, it’s specifically sold as an engraver. But given the fact that you can get one of these little guys for around $70 USD shipped, it’s hard to complain.

Now I wasn’t 100% sure what I would do with a laser engraver, but I thought it would be a good way to test the waters before putting serious money (and time) into something more powerful. Plus, if I’m being totally honest, I wanted to start on something on the lower end of the power spectrum because I’m terrified of blinding myself.

Made of black laser-cut acrylic and held together with stainless steel cap screws, the DK-8-KZ has the look of something that was built from a kit but with good enough fit and finish that it doesn’t feel cheap. Not to say it could be called substantial by any stretch of the imagination, as it stands just under 8 inches tall. On one hand that means it’s convenient to toss up on the shelf when you aren’t using it, but the reality of the DK-8-KZ’s diminutive size is that it has an extremely small working area of approximately 40 mm x 40 mm.

There’s an excellent reason the DK-8-KZ is limited to such a small and specific range of motion: both the X and Y axis of the device are riding on hardware reused from optical drives. I get the impression that a warehouse full of largely-obsolete optical drives was found in China, and somebody had the brilliant idea of using their accurate motion as the basis for a whole line of tiny laser engravers. (Editor’s Note: we tried to find the earliest occurrence of such a device on Hackaday, and came up with this machine. See if you can find something older!)

The NEJE DK-8-KZ does come with a disc that has drivers and software for the device, but I promptly threw that in the trash. For one, I wouldn’t trust the pack-in software with this device any farther than I could throw it. But more practically speaking, I don’t have a Windows computer anymore so it wouldn’t have done me any good. Luckily, the NEJE DK-8-KZ has a relatively simple control protocol and there are a few projects out there to get it up and running.

Personally, I’ve been using EZGraver and have had excellent luck with it. It’s open source and works on Linux, Windows, and OSX. It even has a command line interface if you don’t want to use the Qt front-end.

The workflow is pretty simple with EZGraver. After connecting to the hardware, you load up a 512 x 512 black and white image and adjust the scale and rotation controls as necessary. There’s also a setting for how long you want the laser to burn for, which becomes important when dealing with different materials. Once the preview looks good and your burn time is set, you upload the job to the NEJE DK-8-KZ and click “Start”.

One thing I found interesting with the NEJE DK-8-KZ is that the computer doesn’t directly control it. The image and the selected settings are uploaded into the machine, and after that you can disconnect the computer and use it un-tethered by simply hitting the red button on the top of the machine to start the burn.

I don’t want to beat up the NEJE DK-8-KZ too bad, as it’s very cheap, and you can assume that the experience isn’t going to be perfect when you’re buying a product made of DVD drive carcasses. But there’s still a few things that need mentioning if you decide to walk down this path.

First, powering the thing. There’s a 5 V power barrel-type power connector on the side of the device, for which you need to provide your own AC adapter. But even if you’ve got that connected, the board needs its own 5 V over the USB connection. Long story short, even if you aren’t using the NEJE DK-8-KZ connected to your computer, you need to have both ports powered. This isn’t a huge deal with how common 5 V USB power adapters are (I’ve got a whole box of them), but seems pretty sloppy.

Probably the biggest issue I found with the NEJE DK-8-KZ is the quality of the optics. You need to manually focus the laser onto the object you’re working on, as the focal point needs to be as tight as possible to get a good burn. The only problem is that the focusing lens dances all over the place when you turn it. There’s no way to bring the laser into focus without the focal point drifting around, which means doing something as simple as pausing a burn to adjust the focus becomes effectively impossible.

Lastly, while it isn’t a huge deal, I have to bring up how they handled homing the laser. There’s no end-stop switches as you might expect, and instead the firmware simply runs the motors backwards for 20 seconds or so; making a terrible grinding noise every time you turn it on.

Of course, the real question with something like is how well does it actually burn. As it turns out, quite well. I’ve burned paper, cardboard, wood, and plastic with excellent results. It can easily cut through paper and 3M painter’s tape, which holds some interesting possibilities in terms of making stencils for painting and etching.

If you’re reading Hackaday you probably want to know if you can use the NEJE DK-8-KZ to make PCBs. In the past we’ve shown somebody using a very similar device with pre-sensitized photoresist PCBs, so that should work well enough.

But what if you just have some regular copper clad board? I tried spraying a scrap of board with black paint, but the laser doesn’t seem strong enough to ablate it away fully. I had much better results using black nail polish, but still haven’t quite found the proper settings to get a clean burn all the way through. When viewed under a microscope you can see that the laser isn’t completely removing the nail polish, which has hindered my attempts at etching so far.

I haven’t given up yet. The trick might be multiple passes with the laser, or even some kind of abrasive or brushing after burning the board to knock off the last little bits of nail polish. I plan on keeping at this, and will post an update if I manage to get some good boards out of the NEJE DK-8-KZ.

The NEJE DK-8-KZ is such an old hack that if somebody sent it into the tip line as their own project, we’d ask ourselves if we wanted to run yet another CD-sled CNC machine. (Sure, we would!) That’s not meant to knock it — honestly I’m impressed at what NEJE managed to do with what is essentially e-waste. Turning a dirty hack like that into a product is worth at least a hat-tip, if not a few Jolly Wrenchers. It isn’t perfect, but once you get used to the quirks the results speak for themselves.

This thing isn’t nearly as good as other “cheap” lasers out there, and it doesn’t hold a candle to something like the K40. But for $70, I think it’s a pretty great buy. It’s unlikely to be your last laser, but it’s a great choice for your first one.

I wonder if combining chemical etching with the laser would work. Like, cover plain copper clad with a thin dark-colored layer of weak etchant that works very slowly at room temperatures, but speeds up when heated.

Done with this machine to engrave metal, with a matte black spray paint on aluminium sheet. After burning the matte paint, a little brushing with dish scrubber sponge to remove still attached paint flakes on the burned area, then some drops of 35% hydrochloric acid on the surface. 30s after, I had around 0.1mm on aluminium removed. Then a water cleaning, and after an acetone bath removed the remaining paint to have a nicely engraved aluminium plate.

Wouldn’t simply spending a bit more for a solid state laser to mount on one of your numerous 3d printers have been a better plan?

i saw a kit from jtechphotonics for this that is compatible with various 3d printers. for example it would connect to my printrbot by using the fan header to control the laser. there are several diode options form 1w to 3.8w. prices ranging in the $260 – $475 range. it looks like a nice kit but the price kills it. i think id just get me a diode off ebay, or better yet, the scrapheap, and make my own. id have to wire up a mosfet to toggle the laser on and off using the fan signal and then its just a matter of generating the right gcode.

“Lasers seem like an interesting next step in my quest towards complete in-house fabrication capability, so I started researching cheap setups to get my feet wet.”

Some “specialized cooking appliances” or gadgets are great. Others just get in the way… (sigh!)

Made me laugh crying too. Then i read he´s terrified of getting blinded by lasers, so he buys a cheapo 1W engraver WITHOUT ENCLOSURE. Meatbags are SO approximate illogical beings…


That is “Type2:3D” which is “filament”, if you select “Type1:3D”, it shows “laser” and a price of $149.99 (sigh!)

He found the cheap price from the “list of options with something cheap to get up in the results scam”, The actual printer was $149.99

Damn! You guys are right. All I did was copy and paste the model number from the article and ebay showed up in a search and it said $32 BUT, when you actually choose that model shown in the photo, it is $150. Sorry I missed that you guys. What a scumbag way of listing something. I would have been very disappointed had I ordered it.

Yeah, this actually caught me a couple times as well. They way the make the listing it seems like you’re getting the whole machine, but it’s just the replacement laser.

The defuse reflection from a 1W laser can already damage your eyes. So, safety first on these things!

1W is in the put-it-in-a-box category. That’s why we have webcams. Because you don’t care if the webcam goes blind.

Question: Obviously for certain materials, certain metals for example, I imagine this simply wouldn’t apply– The thermal dissipation of the material would simply be too high. But, otherwise, with a ‘low power’ laser such as this, if you just let the beam ‘sit’ in one area, might it, eventually, possibly cut through the material ? Or it just does not work that way… ?

Doubt it, you need enough power density to vaporize the metal. You need to be able to quickly blast the top surface off, which rapidly increases the absorptivity, yielding higher energy transfer and the hole gets deeper. Metals have higher boiling points, so it’s hard to get that initial ablation of the surface. I dunno a whole lot about it however, it might work with a very thin foil, like much thinner than tin foil kinda thin.

I have a general question about laser cutters. Do they have a lower power setting that allows them to act as engravers? I assume so, but thought I should ask.

Depends on your controller. Some have PWM control, some have TTL to constant current control. Some do not. So you simply run it at faster speed across the item.

Working on my own laser PCB maker as well. Have decided to go the dry film photo resist route. Expose it with the laser and etch away. Seems like it will honestly be the most reliable as well.

If you can get the beam right, UV laser + UV cure resist is a great technique for the quick and dirty.

That’s the plan! Strapping a Suka-K3 style uv laser on my heavily modified XYZ davinci 3d printer if it all works out ~7″x7″ pcb fabrication space :D Joy of using it on my printer is I get z axis adjustment so I can dial in my focal height nicely if needed with out playing with the lens!

I have an Anet A8 laying around after getting my CR-10S. I was wondering if I could do this with the Anet. I found this link http://lokspace.eu/anet-a8-3d-printer-laser-engraver-mod/ where they used an Anet A8 as laser engraver.

When I used laser / paint PCB etching methods, I’d rub the surface with a little bit of toothpaste to get the excess powder and material out of the grooves.

I’ve been looking at the PCB making process, and the consensus seems to be that ablating pure copper is not going to work because the copper acts as a giant heat sink and also has a tendency to reflect back into the laser which is bad. I have built a X-Y-Z Grbl capable frame with a view to adding multiple heads – etching or drilling PCBs, lasering PCBs and also spot placement of solder paste (which is really easy to do automatically with a simple bit of OpenCV on the board layout to get the pads identified — whether it’ll actually work satisfactorily remains to be seen!). Like Tom, I think there is scope for multiple passes with copper clad board, and also for combining several small lasers into a more powerful one using e.g. hexagonal quartz rod (not my idea, stolen from a post on a physics board on the net).

Thats why you use a cover layer of paint. You are burning the paint away, leaving a negative you can etch, much like toner transfer methods. No one is trying to burn copper with a diode laser.

I’ve talked to a few people who own laser engraving businesses that have picked up a few of these for small, simple jobs, and are quite pleased with them. For example, they are great to take to trade shows/etc. to make small ornaments/pendants/etc.

It is so simple to get a photosensitized board and print the traces on transparencies with a laser printer, why go to all this trouble? My guess is the quality is superior to anything you will get with this technique.

It is so simple to get a photosensitized board and print the traces on transparencies with a laser printer, why go to all this trouble?

I picked up one of these last year and agree with all points in the article. For the price it is a neat little gadget. Successfully cut tape templates that were later used with a bead blaster to etch a pattern onto glass mugs. Made some interesting coasters. Etched contact details into the fake leather of a phone case (warning: toxic and corrosive gas, use an extractor). I would really like the work area to be twice the size but as stated in the article it’s not possible using this cheap re-purposed hardware.

Man, that’s a tiny heat sink. My 0.5W has one thats almost 1.5×1.5×3 inches big, not that tiny 0.4 inch mess.

I bought one and did some research. There is my page with (RAW) data gathered. It’s really rougth, and I may never update it, but maybe the serial data will interest someone : (Warning, French page)http://www.tdms.fr/diy/DK-8/

“I tried spraying a scrap of board with black paint, but the laser doesn’t seem strong enough to ablate it away fully. I had much better results using black nail polish, but still haven’t quite found the proper settings to get a clean burn all the way through.”

Although it could be said that this is more than half-way to the toner transfer method anyway, make some all-black pages on a photocopier to avoid the need to have your own laser printer and use an iron to transfer the toner over to the PCB.


Has anyone used it for cutting fabric? (If that works, it’ll be an easier sell with SWMBO -She Who Must Be Obeyed) B^)

Generally, no. Works best with synthetics, but lasers generally vaporize the material, rather than actually burning them. On white and light fabrication, there may be slightly coloring but peroxide bleach (non chlorine) works in laundry to remove. If you are really concerned, masking tape prevents most discoloration. Just make sure cutting rate is high enough.

Built my current engraver for under $100.. $3 for Arduino Nano clone running GRBL, LaserGRBL software on PC, geekcycled rails (THK) for around 8×10″ workspace, EasyStepper drivers at $3 each, and $59 for 2.5w 450nm Blu-ray including goggles off eBay.

With 2.5w cutting up to 1/4″ basswood is possible with multiple passes, as is engraving glass (matte paint on backside, engrave through glass, paint ablation performs engraving) using TTL grayscale engraving is tricky but possible. Dithered image works better, as rails are leadscrew type, resolution of greater than 20 lines per mm is possible.

“Magnified 250X” needs a scale to be meaningful unless you know how big the image is when it is displayed on my screen.

I installed ExGraver on the Linux laptop last night. For some reason “Brave” would not download the .zip file from GitHub, but FireFox did. One step at a time…

I also bought a 1.25 inch (3.175 cm -Jenny) wooden dowel. I intend to slice it into disks, and make them into “wooden nickels” for an upcoming event.

EzGraverUi (I mis-wrote ExGraver above) needs to be run under sudo, otherwise it didn’t give me permission to use the USB ports of the laptop to control the engraver.

On Linux, a permission to access USB device is required. It’s possible to run EzGraver as root, like “sudo EzGraver”, but it’s safer to enable access for users. Create a file /etc/udev/rules.d/99-engraver.rules with the following contents (substitute the actual vendor ID for XXXX & actual product ID for YYYY):

Unfortunately I am a Windows user and I tried using the drivers with Win10 to no avail so I dedicated a Win7 PC no AV or internet access just this box to the task and still nothing on the latest drivers from the web site. I am at a loss, I have tried many things and right now it’s a brick. I am looking for some 2015 or 2016 drivers that support this OS but not much luck there. You can’t contact the vendor , surprise there. Otherwise it looks cool for 70 bucks..

They are kinda junk. There’s a procedure and program (Google pl2303 fix) that works, but the pl2303 chip just generally seems crap.

I’d recommend swapping it with a ch340g or other usb-serial, or pull the Atmega from a spare Arduino and use the comm lines.

Ya I am not sure what that is. but I do appreciate the info this gives me something to read up on and an education on these USB controllers. Thank you for the info and your time

Actually while reading this stuff, I wanted to note that I don’t even get this far. I am getting the USB not installed correctly and at the device manager it shows the yellow triangle that it didn’t like the device I am suspecting. If you have any input for this part to I would appreciate any info you may have.

Just got one of these. Supplied software appears to work fine. ezGraver didn’t work. It engraved the first few mm of the image and then just stuck on a line…

It has a battery inside but no on/off switch and it stops engraving if you disconnect the usb. So any idea why there’s a battery in there? (just a power reserve?)

Wow, yours sounds a lot different than mine! Not sure about the battery you mentioned, (not even sure if mine has one) but I wonder if it would have enough power to run both the laser and motors alone.

Turns out, mine is the DK-8-FKZ, which uses the battery to provide high current for the laser, without needing the external 5v power supply.

I have the DK-8-FKZ also. Unfortunately ezgraver didn’t work for me either. Which is a shame because the mfg software is horrible. If anyone finds an alternative, please let me know.

Damn, it worked like a “charm” for me, except for a few problems with burn time, some steps will just reset it, some others just work.

In my experience the software provided for the device would have been optimized for it. The focusing issue may have easily been solved by the software. Could be wrong but it would be interesting to see if there is any improvement in the machine’s function.

Along with the progress of society and the development of science and technology, leather products are being more widely used in various applications. Leather products not only create infinite value, but also play an indispensable role in daily life, such as for clothing, shoes, gloves, sandals, fur hats, belts, watch straps, leather cushions, car seats, and steering wheel covers.

Traditional technology for leather processing mostly adopts cutting, embossing, and embroidery machines, which operate at slow speeds and have a high manpower cost with sometimes less than high-quality results. As a consequence, this fundamentally restricts the development of the leather industry.

In recent years, because of the wide application and popularization of lasers, leather laser cutting machine use also rose at this time. High-energy, high-power-density carbon-dioxide (CO2) laser beams can process leather rapidly, efficiently, and continuously. Laser cutting machines employ digital and automatic technology, which provides the capability to hollow out, engrave, and cut in the leather industry.

The laser cutting machine has broken the limits of traditional manual and electric cutting with their slow speed and pattern layout difficulty. The CO2 laser fully solves the problem of unreachable efficiency and waste of materials. The speed of laser cutting is high and the operation is simple, which involves inputting the graphics and piece size to the computer to enable the machine to then cut out the finished product in a non-contact manner.

The advantages of the leather industry adopting CO2 laser cutting are obvious. Compared to the traditional way of cutting, laser cutting is low in cost and consumption, has no mechanical pressure on the workpiece, and the effects of precision and speed are very good. Laser cutting also has the advantages of safe operation and simple maintenance, and the equipment can operate continuously.

The CO2 laser beam in the leather cutting machine is focused into a small spot so that the focal point achieves a high power density, quickly converting photon energy into heat to the degree of vaporization, forming holes. As the beam on the material moves, the hole produces a narrow cutting seam continuously. This cut seam is little affected by residual heat, so there is no workpiece deformation.

The size of the leather that is laser-cut is consistent and accurate, and the cut can be of any complex shape. Using computer graphic designs for patterns enables high efficiency and low cost. As a result of this combination of laser and computer technology, the user making the design on computer can achieve laser engraving output and change engraving at any time.

The leather industry is experiencing a technology change with specialized laser leather cutting machine breaking the low-speed, hard typesetting of traditional manual and electric shears, fully solving the problems of low efficiency and waste of material. By contrast, the laser cutting machine is high-speed and easy to operate, as it only involves entering the graphics and size to the computer. The machine will cut the entire material into the finished product without tools and molds. The use of laser cutting to achieve non-contact processing is simple and fast.

Leather shoe laser cutting machines can perfectly cut synthetic leather, polyurethane (PU) leather, polyvinyl chloride (PVC) artificial leather, leather wool, semi-finished products, and a variety of leather fabrics.

Laser cutting machines accomplish a wide range of applications. CO2 lasers can cut most organic materials such as leather, cloth, plush, PVC, Plexiglas, wood, and other non-metal materials. In terms of shoe materials, cutting and blanking of surface materials, perforation, small flower patterns, and shoe-like paperboards all can be done perfectly. Integral exhaust fans remove fumes from the cutting area.

MarketResearchNest.com presents “Laser Cutting Machines Market Research: Global Status & Forecast by Geography, Type & Application (2015-2025)” new Research to its studies database. The records spread across 81 pages with more than one tables and figures in it.

This comprehensive Laser Cutting Machines research report includes a brief on these trends that can help the businesses operating in the industry to understand the market and strategize for their business expansion accordingly. The research report analyzes the market size, industry share, growth, key segments, CAGR and key drivers.

According to 99Strategy, the Global Laser Cutting Machines Market is estimated to reach xxx million USD in 2019 and projected to grow at the CAGR of xx% during the 2020-2025. The report analyses the global Laser Cutting Machines market, the market size and growth, as well as the major market participants.

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Global Laser Cutting Machines in its database, which provides an expert and in-depth analysis of key business trends and future market development prospects, key drivers and restraints, profiles of major market players, segmentation and forecasting. A Global Laser Cutting Machines Market provides an extensive view of size; trends and shape have been developed in this report to identify factors that will exhibit a significant impact in boosting the sales of Global Laser Cutting Machines Market in the near future.


Moreover, the research report assessed market key features, consisting of revenue, capacity utilization rate, price, gross, growth rate, consumption, production, export, supply, cost, market size & share, industry demand, export & import analysis, and CAGR.

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Photo laser engraving is a great way to turn your pictures into personalized and functional objects. Bring your pictures into a new dimension with photo laser engraving!

We’re always looking for excuses to play with lasers, and laser engraving is a great place to start. The basics of the process are easy to understand – laser engraving is the process of carving a design into an object using a concentrated beam of energy. The laser acts like a knife does when you whittle something but is much more precise since it’s guided by a machine instead of human hands. It also produces much less waste because of its precision.

Both of these properties make laser engraving ideal for transferring photos to another surface. You don’t lose the important details that make photos the perfect records of your best moments with laser engraving. Plus, you have a huge variety of materials to choose from, including plastics, wood, glass, stone, and metals, which makes the process a popular way to create art and jewelry. It’s just a simple step up to laser engraving your photos in the same way.

Lasers engraving has a lot of industrial applications, as well. It acts in the same way, as a precision carving tool that helps with detail work such as cutting internal lenses for machines and adding an image directly onto printing plates to avoid film. Laser engraving has revolutionized all areas of photo reproduction. Read on to take advantage of its ease of use and powerful effect!

You’ve got a lot of options here. Be aware that they all accept engraving differently and you should adjust accordingly depending on what you use.

Laser engraving your photos is a simple process, but it does require a few specialized tools and materials. Here’s what you need to get started:

If you’re looking for a laser engraving machine, make sure to check out our article on the best laser engravers. And if that selection still isn’t enough, here are a few additional options:

Now that we’ve prepped you, it’s time to get to the fun part: playing with lasers! And don’t worry, laser engraving your photos takes a lot less time and effort than blowing up the moon. Here are the steps:

Now that you know the basics, here are a few ways to make sure laser engraving your photos goes smoothly for you.

If you can’t or don’t want to buy your own machine, you can find a number of services that will laser engrave your photos for you if you send them your files and their fees. Here are a few we recommend:

Congratulations on your new skills in laser engraving photographs. Go ahead and make yourself an award with your face on it – you deserve it!

License: The text of “Photo Laser Engraving – How to Make Laser Engraved Pictures” by All3DP is licensed under a Creative Commons Attribution 4.0 International License.

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Post time: May-14-2019
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