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The Additive Manufacturing Market is expected to reach above $93.36 billion by 2031
Additive manufacturing Market Size, Share, Forecast, & Trends Analysis
According to the latest publication from Meticulous Research®, the additive manufacturing market is projected to reach $93.36 billion by 2031, growing at a compound annual growth rate (CAGR) of 20.3% from 2024 to 2031. This growth is primarily driven by the increasing demand for producing complex parts, reducing manufacturing costs, minimizing waste, and improving product development and supply chains. The market also benefits from the ability to easily customize products and support large-scale production. However, growth may be restrained by challenges such as limited build sizes and the costs associated with pre-processing and post-processing.
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Opportunities for growth in the additive manufacturing market include the growing use of 3D printers for producing functional end-use parts and the rise of composite 3D printing. Nonetheless, concerns about piracy, unauthorized distribution, and a lack of skilled professionals could pose challenges to market expansion.
Key trends in this market include on-demand production of spare parts, increased product customization, and the integration of artificial intelligence (AI) into 3D printing processes.
Market Segmentation
The additive manufacturing market is segmented by Offering, Technology, End User, and Geography:
By Offering: The market is divided into Hardware, Software, Materials (Polymers, Metals, Ceramics, Composites, and Other Materials), and Services. Among these, the Services segment is expected to hold the largest share, above 52.8%, in 2024. This segment includes services such as additive manufacturing services, education, repair and maintenance, consulting, and training associated with hardware and software. The large share is driven by the growing number of service providers, increasing reliance on these providers by end users, and the benefits of outsourcing. Additionally, the rising deployment of 3D printers across industries is expected to increase the demand for support and maintenance services, enabling business process improvements and continual modifications.
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By Technology: The market is segmented into Fused Deposition Modeling (FDM), Selective Laser Sintering (SLS), Stereolithography (SLA), Direct Metal Laser Sintering (DMLS), PolyJet, Multi-Jet Fusion, Digital Light Processing (DLP), Binder Jetting, Electron Beam Melting (EBM), Directed Energy Deposition (DED), Laser Metal Fusion (LMF), Selective Absorption Fusion (SAF), LCD 3D Printing, and other technologies. In 2024, the Fused Deposition Modeling (FDM) segment is expected to account for the largest share at 11.5%. This dominance is due to the expanding application areas of FDM technology, such as automotive, aerospace, general manufacturing, healthcare, consumer goods, and jewelry, its cost-effectiveness, and its growing adoption by various manufacturers.
By End User: The market is segmented into Consumer Products, Healthcare, Automotive, General Manufacturing, Electronics & Semiconductors, Aerospace & Defense, Chemicals & Materials, Energy, Oil & Gas, and Other End Users. The Automotive segment is expected to register the highest CAGR of 22.4% during the forecast period. This growth can be attributed to the use of additive manufacturing in rapid tooling and fixture production, optimizing component performance, and integrating multiple functions into single parts. Automotive manufacturers and aftermarket suppliers utilize additive manufacturing to produce spare parts, replacement components, and obsolete parts on demand, enhancing supply chain resilience and customer satisfaction.
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By Geography: The market is divided into North America, Europe, Asia-Pacific, Latin America, and the Middle East & Africa. The Asia-Pacific region is projected to register the highest CAGR of 22.1% during the forecast period. This growth is driven by rapid developments in the region's manufacturing sector, increased digitization, and the adoption of additive manufacturing technologies across various industries. Additionally, a vibrant startup ecosystem in Asia-Pacific fosters innovation and collaboration, further contributing to the market's growth.
Key Players
Key players in the additive manufacturing market include 3D Systems Corporation (U.S.), 3Dceram (France), Dassault Systèmes SE (France), Colibrium Additive (U.S.), Materialise NV (Belgium), Shapeways Holdings, Inc. (U.S.), Canon Inc. (Japan), voxeljet AG (Germany), Optomec, Inc. (U.S.), Proto Labs, Inc. (U.S.), Stratasys, Ltd. (U.S.), EOS GmbH (Germany), Desktop Metal, Inc. (U.S.), Formlabs Inc. (U.S.), and Autodesk, Inc. (U.S.).
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These companies play a critical role in shaping the market by providing a diverse range of products and services, fostering technological advancements, and driving the adoption of additive manufacturing across various industries.
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Phrozen Aqua Red-Clay 8K
PPhrozen Aqua Red-Clay 8K | 3D Drucker Resin für SLA/DLP/LCD 3D Printer | 405nm Standard Photopolymer Druck Harz | 8K Hohe Präzision, Geringer Geruch – Rot (1kg)
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High Precision: With this printer resin, printed parts will have high detail with no deformation or noticeable shrinkage and the final cured pieces are strong without being brittle.
Quick Curing: The UV resins can be rapid prototyping, developed to reduce the forming time.
Rigid & Toughness: This LCD resin Has a good combination of hardness and toughness, which brings easy removal of the model and fine printing details.
Excellent Fluidity: Able to quickly infiltrate models and cure them into shapes, and tend to be making clean up and post-processing finished pieces much easier.
Well Packed: The SLA resin bottle comes packaged safely in bubble wrap and cap are completely intact, surrounded by a tight-fitting air pillow. No worries for leakage.
Buy 3d printer here:
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Dotbit 4Pcs SLA FEP Film 280x200mm 0.15mm Thickness for SLA SLP LCD Light Curing UV Resin 3D Printer
Dotbit 4Pcs SLA FEP Film 280x200mm 0.15mm Thickness for SLA SLP LCD Light Curing UV Resin 3D Printer
Specifications:Size:280x200mmThickness:0.15mmLight Transmittance:92%Fit for:DLP 3D PrinterYDM-YDP-192120
YDM-YDP-215135KLD LCD1250
KLD LCD1260S
Wanhao D8
ILUMI v2 & v3
DLP Photon
YHD-101
Phrozen
Kudo Bean
Anycubic
Creality LD-003
Package Included:4 x FEP Film
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The best resin 3D printers in 2021: the differences between processes, innovations, common uses and things to consider...
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Vaidas shares his experience on his latest creation - SLA 3D printer. Here goes the details so dig in.. ;)
Finally, a few months ago I finished another SLA printer (LCD based). And it works great, prints really well with way faster cure times than I thought. Now I think I can share my experience.
But to begin with, my goal was not to make the smallest and the fanciest device, but it was supposed to be quite adjustable, easy to work with and upgradeable if necessary (or if something goes wrong).
I started to with frame itself. I wanted to make it out of ordinary shelf components so I chose standard aluminum profiles (40mm x 20mm) (image: Profiles). I went for “box” design with two sections: bottom part for electronics and upper part for actual printing chamber. And now, after finally completing this printer, I must say that this design is really comfortable to work with: you can access all segments of the printer from all sides, you can do that very quickly with no stress. You do not have to disassemble the whole printer, when you want to adjust something that is deep within.
Profiles
Aluminum profiles were powder coated using self-made powder coating system (images: Powder Coating, Painted profiles, Powder Machine). It uses old CRT monitor transformer (50k V), paint gun is also 3D printed and uses “Nestea” bottles to feed powder. I was amazed how expensive are powder coating paint guns… and it took as one evening to make one for us.
Powder Coating
Painted profiles
Powder Machine
Profiles were joined together using my own design 3D printed “corners” (images: Frame Assembly, Frame Assembly_2). Each profile was also fixed with M4 screws to each corner. After joining profiles together, I had fully functional frame. See images.
Frame Assembly
Frame Assembly_2
Then it was time for Z axis (images: Carriage Head, Carriage Plywood, Carriage Top). I am a fan of thick linear rails, so I used here 16mm calibrated steel rods. I like thick rods since they compensate well any wobbles that come from usually curved thread. Stainless steel M8 thread was used. Head itself was redesigned “Cristelia” version. I did not like to use only two bearings for carriage, so I made my own carriage that uses 4 linear bearings since that brings way more stability into the system. Build plate and the rest of the head is “Cristelia” design. It is quite good although a bit bulky, but it works well. All in all, Z axis itself after calibrating it, was off only by ~10um within 10cm, i.e. after moving axis from 0 to 10cm, at the top it was off only by ~10um. Since everything was made by hand – that is pretty good. Disclaimer: my hands are not very well “calibrated” I was simply lucky this time :)
Bottom part and printing chamber was separated by hand-cut plywood plate (image: Carriage Plywood). I have chosen wood, since it is less expensive and easier to work with. I coated it with lacquer and it is just fine. At least when you need additional hole, you can make one easily.
Carriage Head
Carriage Plywood
Carriage Top
Now electronics (images: Inside, Dashboard)... First of all, my goal was to design electronics to handle 100-130W LED (I did testing at the end and it handled that power well). I use two PC power supplies (since I have a bunch of those): one for LED and one for remaining electronics (RPI3, Arduino, power for fans, steppers etc.). LED is powered using 300W step-up boost converter. Since I installed powerful 1 ohm resistor, I can measure current usage of LED circuit with voltmeter and with another regular voltmeter (measuring LED voltage drop) I end up having a nice dashboard, which helps me to see actually emitted power by LED and I need that, since I change LED power for my own reasons quite often. Another dashboard screen shows voltages of RPI3 and Arduino (helps to debug any issues). Everything is cooled using a bunch of fans from PCs.
Inside
Dashboard
Now, the LED part… It was (as expected) the most complicated one, where I spent most of my time. I also thought of using an array of LEDs, but after trying a lot of alternatives I went for a single LED. Moreover, it was way easier to work with single LED than with array. I was just not able obtain better results with an array than I did with a single LED. I will add image of light uniformity with single LED (image: Light Distribution). Although I designed everything for >100W LED, I use 50W LED (400-410nm). Since I still think of making daylight device one day, I think this power reserve might be useful later.
Light Distribution
LED assembly (images: Collimator, Collimator Top) consists of a large piece of aluminum plate (image: Heatsink For LED) with additional heatsinks attached at the bottom. PC fan is attached at the bottom as well. LED is screwed on the plate. Then there is first part of the whole assembly (everything is 3D printed, ABS) which holds Fresnel lens on top (see image: Collimator). Then there is second part – mid part, which had a purpose to be short and easily changeable if I needed to adjust distance between LED and LCD, so bear with me, but I did take a lot of precautions. It was easier to print another short part than entire assembly. Last part is top part, which is attached to a plate of black PMMA plate with a rectangular cut, which holds LCD display. There are a few fans to get cooler air inside, I am not really sure now that they are making some sort of impact, so you can say that they are useless, but… oh well: they live there and it seems they are happy. Interior of this collimator is covered with aluminum foil. Foil itself also did not make any serious changes/improvements since Fresnel itself collimated light, but, I would say, it was a little bit better. I did not observe some sort of light unevenness due to the foil (image: Light Distribution). LCD itself was placed into the rectangular cut of black PMMA plate – thus closing system. LCD is the same as used for YHD-101 (KLD). With this setup, I did not notice any heat issues at all. LCD is warm, but that is all.
Collimator
Collimator Top
Heatsink For LED
This LED assembly was fixed to plywood plate that separates bottom part from printing chamber (image: Inner Chamber). I used springs to fix that in place and springs also allow me some sort of adjustments. Another feature is that it helps me to avoid crashes if Z axis accidentally goes to low – springs will compensate that.
Inner Chamber
Frame was covered with milled orange PMMA, which is very easy to remove, when you need to access some parts of the printer. Doors are made out of piano hinge (image: Hinges) and door lock (image: Door Lock) is made using simple magnets and 3D printed parts. At the bottom of the frame, there are adjustable legs (image: Legs), which you can screw up and down to adjust the level of the printer.
Hinges
Door Lock
Legs
VAT I made was a mix of various designs, since I made a lot of them in recent years, this was just a rough assembly which appears to be working really well (image: VAT)
VAT
I have attached image of printed calibrations parts (images: First Print Calibration, Motor)
First Print Calibration
Motor
And at the end, I must say, that everything turned out quite OK and I cannot say that I would do something in a completely different way if I had to start over again. It works OK, maybe it is possible to play again with array version or to simplify collimator assembly, but all in all it does the job.
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From KELANT D100
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Liked on YouTube: QIDI TECH SLA /LCD 3D Printer Shadow 5.5 S Review https://www.youtube.com/watch?v=Y2AxAhn2oA4
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JAMG HE Standard Pro Resin, (1000g, Gray)
JAMG HE Standard Pro Resin for LCD DLP SLA 405nm High Precision & Low Shrinkage 3D Printing Standard UV Photopolymer Resin Suitable for 2K/4K/6K/8K/12K Printers (Standard Pro Gray)
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The little resin printer I showed before is now up for pre-order for $89
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High Precision: With this printer resin, printed parts will have high detail with no deformation or noticeable shrinkage and the final cured pieces are strong without being brittle.
Quick Curing: The UV resins can be rapid prototyping, developed to reduce the forming time.
Rigid & Toughness: This LCD resin Has a good combination of hardness and toughness, which brings easy removal of the model and fine printing details.
Excellent Fluidity: Able to quickly infiltrate models and cure them into shapes, and tend to be making clean up and post-processing finished pieces much easier.
Well Packed: The SLA resin bottle comes packaged safely in bubble wrap and cap are completely intact, surrounded by a tight-fitting air pillow. No worries for leakage.
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SLA 3D UV Laser Printer Machine With Resin China
Additive Manufacturing Stereolithography 3D UV Laser Printing Machine with Curable Resin
Light Curing (SLA) is a high-speed and high-precision 3D printing technology. Ultraviolet laser and liquid ultraviolet curing photosensitive polymer, photosensitive resin, are used to print parts. Controlling the laser beam scanning on the resin liquid surface, the resin liquid surface is solidified to form a cross-sectional film of the scanned parts. After solidifying one layer, a layer of liquid resin is coated on the newly formed film, and the scanning is continued to solidify the film and bond it to the cross section of the previously solidified part. This reciprocating, layer by layer growth, thus printing out the complete three-dimensional parts.
*High speed scan head, high efficiency.
*Negative pressure adsorption scraper, uniform and reliable coating.
*Automatic scan path.
*Detachable table, easy to operate.
*Laser online measurement, technological parameter with full-automatic setting.
*Liquid level automatic control.
*Stable and reliable.
*LCD display.
Product Picture
Specification
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Quick Look: Prusa Sl1 Resin 3D Printer We had the opportunity to explore Prusa’s latest entry into the 3D printing market, the SL1. This is a masked SLA printer, which means that the resin is cured via a UV lamp, that shines through an LCD screen up into the vat of resin. The current trend in this […] Read more on MAKE The post Quick Look: Prusa Sl1 Resin 3D Printer appeared first on Make: DIY Projects and Ideas for Makers. https://buff.ly/2P7TvMf
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Longer Orange 30 LCD SLA 3D Printer is an affordable way to create models - https://thegadgetflow.com/portfolio/lcd-sla-3d-printer/
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MYR 726.13 31%OFF | KINGROON KP6 Mono 3D Printer with 6.08 inch 2K Monochrome Screen LCD UV Resin Printers High Speed 3D Printing SLA 3D Printer
MYR 726.13 31%OFF | KINGROON KP6 Mono 3D Printer with 6.08 inch 2K Monochrome Screen LCD UV Resin Printers High Speed 3D Printing SLA 3D Printer
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