3devo Introduces Two New Series of Filament Extruders - 3DPrint.com
18 Dec
Blog

3devo Introduces Two New Collection of Filament Extruders – 3DPrint.com

3devo is a young company known for its filament extruders, which include the NEXT 1.0 and the 3devo Advanced. The Dutch company also markets a plastic shredder as part of its mission to simplify filament manufacturing and recycling. Now 3devo has announced two new product lines, the filament manufacturers the Precision series and the Composer series. According to 3devo, the new filament manufacturers are further simplifying the material manufacturing process.

“Our NEXT filament maker has found numerous uses in industries ranging from education and research to manufacturing and aerospace,” says 3devo. “They brought users a number of benefits, including shorter lead times, less material waste, and better control over material production. They also made materials research and customization easier, and introduced the precision of industrial filament manufacturing into desktop-based setups. However, we have recognized that our filament manufacturers can serve these purposes even better – if they focus on specific requirements. Our new filament manufacturers in the Precision and Composer series are specialized, results-oriented machines designed to simplify the material manufacturing process. Each in a different way. “

The Precision series of filament manufacturers enables mass production of 3D printer filaments with higher speed and improved diameter accuracy. It has a high-flow extruder screw that can be used to produce filaments without losing diameter tolerances.

The Composer series is designed for mixing and experimenting materials. Users can develop custom filaments from a wide variety of polymers and additives. It has a mixing screw that enables high quality mixing and compounding of the material.

Both series have two additional models that meet material-specific requirements. The Precision 350 and Composer 350 can handle temperatures up to 350 ° C, which means that they can handle materials like PLA, ABS, PC, PS, PETG, TPU, TPE, PPS, PA (6,12,66) and more can. The Precision 450 and Composer 450 can – you guessed it – process temperatures of up to 450 ° C and thus process high-performance materials such as materials from the PAEK family such as PEEK as well as power supplies, PTFE, PVDF and more.

The new filament manufacturers have several upgrades and improvements. Each Precision and Composer model has an improved extruder system with a new “interchangeable” design. The entire extruder system, including the screw, barrel, die head, motor, and heaters, is designed as an independent, removable unit for easy cleaning, repair, and maintenance. Users can easily disassemble and reinstall the system themselves.

In addition, the heating system was upgraded. All precision and composer filament manufacturers contain ceramic tape heaters with four controllable heating zones. Each heater is handmade in-house. The filament manufacturers also have funnels with closable caps to prevent material contamination. After all, the new filament manufacturers each have updated software that improves their thermal stability by up to 35%.

3devo has more in the works – the company is developing a web app with cloud access that will enable active data collection from extrusion tests.

More information about the Precision and Composer Filament Maker series can be found here.

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[Images: 3devo]

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Could this be the validation 3D printing on desktop has been waiting for? Selection of AmazonBasics PETG 3D printer filaments. Image via Amazon
18 Dec
Blog

Amazon now promoting own-brand 3D printer filament

Leading e-commerce platform Amazon has launched its own brand of 3D printer filaments that can be sold and shipped worldwide.

While the current waiting time for the products is 1 to 3 months, the move is interesting because the filaments are available in the AmazonBasics range and bring them in line with common household items like batteries, HDMI cables and lightbulbs.

Could this be the validation 3D printing on desktop has been waiting for? Selection of AmazonBasics PETG 3D printer filaments. Image via Amazon

AmazonBasics 3D printer filament now available

Filaments of the Amazon brand are available as PETG, PLA and ABS plastics in various colors. A single coil alone carries 1 kg of material and is manufactured with a standard diameter of 1.75 mm.

The spool design includes a small window on the front that allows the user to check how much material remains to be processed. The material is also supplied in a resealable storage bag to protect it from damage / contamination when not in use.

A single spool of AmazonBasics filament can be purchased for $ 19.99, and a multipack of 5 filaments is available for $ 79.99 excluding shipping, which is roughly the average price for that amount of material.

Variety of AmazonBasics PLA colors. Photo via AmazonVariety of AmazonBasics PLA colors. Photo via Amazon

3D printing on Amazon

The first commercial 3D printing activity on Amazon was announced in 2013 when the website opened its 3D Printers & Supplies Store, selling consumer machinery, accessories and consumables including filaments such as eSUN, BuildTak and 3D Prima.

Since then, the company’s calm commitment to technology has gradually been evident through a series of research and development projects.

While the filaments may not compare to an Amazon mobile 3D printing service or a top-secret 3D printed drone lab, it certainly got the community talking.

AmazonBasics PETG. Photo via AmazonAmazonBasics PETG. Photo via Amazon

Finding a potential supplier

Currently, the filament of the AmazonBasics PETG 3D printer is listed with an average shipping date of 1 to 3 months. The other two types, PLA and ABS, are marked with “Temporarily out of stock”.

There are ratings for every material. Some are from high-ranking reviewers in the site’s “Top 1000”. Others come from members of Amazon’s Vine Voice program, which is invite-only and provides access to pre-release products in exchange for writing reviews.

Data on these reviews suggests the product was only released recently, apparently in early July 2018.

According to Terry, a Vine Voice contributor, According to Terry, an associate at Vine Voice, “This 1.75mm PETG filament for 3D printing from AmazonBasics seems to print well with no problem as long as your print bed is hot enough.” Screengrab via Amazon

In the rumor recognized by Trochlea subreddit r / 3Dprinting, rumors also circulate about the supplier behind filaments of the Amazon brand. Some users recommend Hatchbox or AMZ3D, two of the most popular filament brands listed on Amazon, as potential suppliers.

Amazon itself, on the brand’s About page, reportedly made all AmazonBasics products in Taiwan and China.

For more information on this news, follow the 3D printing industry on Twitter, as we do on Facebook, and subscribe to our regular newsletter. Join 3D Printing Jobs now to post and seek new opportunities in engineering, marketing, and more.

The picture shown shows the filament of the AmazonBasics 3D printer. Photo via Amazon

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World first: Implant-grade PEEK filament developed for 3D printing
18 Dec
Blog

World first: Implant-grade PEEK filament developed for 3D printing

The chemical company Evonik (Essen, Germany) has announced the development of a PEEK filament in implant quality for 3D printing. The material was developed for FFF (Fused Filament Fabrication) technology and is based on Vestakeep i4 G, which has long been used in spinal implants, maxillofacial surgery and in sports medicine.

Evonik also said that it will offer a more cost-effective trial version of the PEEK filament in order to offer potential customers a cost-effective way of adapting the processing properties of the high-performance plastic for printing processes. The test material has the same processing and mechanical properties as the implant material, but without the documentation required for approval in applications for medical devices.

The test quality will be followed by a Vestakeep i4 G with implant quality in the first quarter of 2019.

The natural colored filament with a diameter of 1.75 mm is wound on 500 gram spools, which are suitable for direct use in standard FFF 3D printers for PEEK materials.

In similar news, the German company Apium Additive Technologies successfully processed PEEK filaments based on Vestakeep i4 G on its Apium M220 series printer for medical applications.

The PEEK filament and M220 3D medical printers were manufactured in response to growing customer demand for end-use patient-specific devices, reports the 3D printing industry. According to the company, the new production technology means a reduction in lead times and costs for the manufacture of implants.

Apium will present these developments next week at the additive manufacturing trade fair in Frankfurt.

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Blending PLA and PBS Creates a Better 3D Printer Filament - 3DPrint.com
18 Dec
Blog

Mixing PLA and PBS Creates a Higher 3D Printer Filament – 3DPrint.com

In an article titled “Making and Characterizing Poly (butylene succinate) / Polylactide Blends for 3D Printing to Model Enamel Deposition,” a group of researchers discuss how to use a new type of biodegradable material with high strength and toughness FDM 3D have developed printing. A number of poly (butylene succinate) (PBS) based polymer materials were blended with PLA. PLA is a popular and effective 3D printing material, but it is brittle with extremely low elongation at break. Therefore, better, more ductile materials need to be developed. PBS is a semicrystalline aliphatic polymer with excellent processability, thermal stability and biodegradability. It is also very ductile and has a relatively low melting point.

“However, there are few published studies on 3D printing with PBS.” The researchers point out. “One reason for this is that its low melt strength makes it difficult to continuously form monofilaments when extruding, which causes printing to fail halfway. In addition, the distortion caused by the relatively large volume shrinkage during cooling is likely to occur after crystallization, resulting in defective products. Modification of PBS is therefore absolutely necessary in order to solve the disadvantages mentioned above and to make the material suitable for FDM printing. “

Mixing the two materials can combine their advantages and compensate for their weaknesses. Researchers made PBS / PLA blends of various compositions to validate their suitability for 3D printing. The rheological, thermal and mechanical properties of the blends were studied and various samples were 3D printed with the filaments to assess their suitability for FDM 3D printing technology. The interlayer bond strength in the 3D printed samples was also evaluated.

According to the researchers, all mixtures showed excellent processing properties and can be extruded as monofilaments with a diameter of 1.75.

“As the PBS content increases, the elongation at break and the impact resistance of the mixtures arise,” they continue. “However, the distortion of the printed rods increases due to the greater volume shrinkage that results from the higher degree of crystallinity in the mixtures. In addition, the interlayer bond strength improves due to the reduced melt viscosity. If the PLA content in the mixtures is not less than 40% by weight, the FDM printing can proceed smoothly without spatial distortion or detachment from the platform at room temperature. PBS60 / PLA40 and PBS40 / PLA60 are the optimal mix compositions, taking into account both the material toughness and the deformation of the printed rods and the adhesive strength between the layers. “

Models with porous structures can be successfully 3D printed using PBS60 / PLA40 and PBS40 / PLA60 filaments, and good dimensional accuracy and glossy appearance of the printed structures were obtained. Compared to commercially available 3D printing materials, the mixtures showed both high rigidity and excellent ductility.

“In addition, these materials offer the possibility of meeting energy-saving and environmentally friendly requirements at a relatively low printing temperature and without heating the carrier platform,” the researchers conclude. “With a pearlescent sheen and good mechanical properties as well as dimensional accuracy, the bio-based PBS / PLA mixtures are therefore new and promising materials for the production of FDM filaments for applications in many areas, especially for architectural design. In addition, our study is expected to provide methods to evaluate whether or not a thermoplastic polymer material is suitable for FDM printing. “

The authors of the paper include Qing Ou-Yang, Baohua Guo, and Jun Xu.

Discuss this and other 3D printing topics on 3DPrintBoard.com or share your thoughts below.

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Budget Dehydrator Gives Your Damp Filament A Second Chance
18 Dec
Blog

Finances Dehydrator Provides Your Damp Filament A Second Likelihood

If you’ve had the misfortune to leave your 3D printer filament outside on a muggy day or, heavenly, shower with it, it’s likely quite humid. Not only does moisture make your printer sound like rice crispies, it also ruins the finish and causes filament to contract into thin strips between different geometries on the same layer. Fortunately for both of us [SafetyGlassesRequired] and [Joe Mike Terranella] Give us the breakdown of how to take a pair of Snippers and about $ 40 in cash to dry out our filament, far from the possibility of ruining nearby kitchen stoves.

If you’ve been circling the 3D printing community for a long time, you may have heard of this trick by now. But with the arrival of an oddly culinary-looking device called the PrintDry, we can’t keep the elephant in the room silent for long. Instead of risking our own pennies and getting stuck with a device that just jerks the lid of the box, [SafetlyGlassesRequired] and [Joe Mike Terranella] Please prove our suspicions once and for all: A dehydrator works perfectly at drying all the filament we left out in the rain!

Clumsiness aside, a dehydrator isn’t a bad investment in the long run. Not only can we keep our stash dry, but we can also give all that giveaway filament (dug out of the trash) a second life by returning it to a clean, dry state.

These dehydrators toast all of the moisture from your filament, but do not keep it dry while printing. For this problem, you need to summon a heated dry box like this one.

[Joe Mike’s] The solution costs about $ 40. If you can do better, let us know in the comments.

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Series of test prints made from Amazon Basics filament. Photo from the 3D printing industry
18 Dec
Blog

Evaluation: Amazon Fundamentals 3D printer filament PLA and PETG

Recently, the leading online marketplace Amazon sparked the rumor mill for 3D printing with the launch of its own Basics FFF / FDM filament brand. To examine the new range of materials for themselves, the 3D printing industry ordered two spools of the filament.

This test examines the print quality of Amazon Basics Black PLA and Red PETG using standard parameters set by our engineers in the 3D printing industry. The tests were carried out using two inexpensive desktop 3D printers, a Snapmaker 3-in-1 and a Wanhao Duplicator 9. The printing profiles for each of these machines are recorded at the end of the article.

Series of test prints made from Amazon Basics filament. Photo from the 3D printing industry

Amazon Basics Filament Unboxing and Delivery

When ordering Amazon Basics filaments, a delivery time of 1 to 3 months was initially specified. With the order on July 25th, the coils arrived on August 14th. The wait on delivery is expected as the order was taken by Amazon.com and the spools were initially sent to a company depot in California prior to shipping to the headquarters of the 3D printing industry. The filament is currently at an early stage of availability. As soon as the demand is assessed, Amazon could update the long delivery times.

Upon arrival, both coils were neatly packed in cardboard boxes and individually sealed with a bag of desiccant in resealable packages to protect them from dust / contamination.

The windows in the coils are a helpful feature in the design, and details of the materials are given in five different languages ​​(German, French, English, Spanish and Italian) for America and Europe. This suggests that Amazon plans to make the filament available in a larger number of regional outlets in the future.

Unboxing Amazon Basics red PETG filament. Photo from the 3D printing industryUnboxing Amazon Basics red PETG filament. Photo from the 3D printing industry

Calibration test

For each filament, the engineering team printed three calibration test models in 3D: a 3DBenchy, an XYZ cube, and a Cali Cat. These models were 3D printed to get the optimal quality of the filament with a layer height of 0.2mm on both 3D printers and a printing speed of 0.2mm 40 mm / s on the Snapmaker and 50 mm / s on the Wanhao Duplicator 9. The models were also 3D printed with 15% filling on the Snapmaker, and the Wanhao Duplicator 9 was set to 10% filling.

Calibration of 3D prints of Amazon Basics red PETG and black PLA. Photo from the 3D printing industryCalibration of 3D prints of Amazon Basics red PETG and black PLA. Photo from the 3D printing industry

None of the 3D printers in this test had extrusion issues when extruding Amazon Basics PETG or PLA. The engineers had no trouble stringing, loading and unloading, or filament breaks when swapping out to try out each model.

Calibration 3DBenchy Boot in Amazon Basics Black PLA on a Snapmaker 3D printer. Photo from the 3D printing industryCalibration 3DBenchy Boot in Amazon Basics Black PLA on a Snapmaker 3D printer. Photo from the 3D printing industry

As a base filament, PLA is best suited for prototypes, toys and figures. With greater rigidity and chemical resistance than ABS, PETG is a polymer for more functional use.

Compared to 3D printing, the quality of the models is consistent. PLA figures are of good quality, although the finish is expected to be better on PETG models.

Layer lines in the red 3D printed PETG calibration models are less visible than those of the black PLA. The surface of the PETG has a shiny gloss.

Side by side comparison of Cali Cats 3D printed in red PETG and black PLA. Photo from the 3D printing industrySide by side comparison of Cali Cats 3D printed in red PETG and black PLA. Photo from the 3D printing industry

Detailed 3D prints

As a further test of the print quality of the material, the engineers printed detailed 3D models of Michelangelo’s Pietà sculpture.

Only the Snapmaker 3D printer was used in this experiment. The layer thickness was set to 0.1 mm with 15% filling and 50 mm / s printing speed.

Both filaments have managed to capture small features, such as eyes, mouth, hair, folds of fabric, of the Pietà model and to achieve a good glossy surface. Removing the supports on a model with such fine features is always difficult, but a clean finish is achieved on any support area.

Michelangelo's Pietà in Amazon Basics red PETG and black PLA. Photo from the 3D printing industryMichelangelo’s Pietà in Amazon Basics red PETG and black PLA. Photo from the 3D printing industry

Tested for purpose

To further verify the quality of the black PLA used for making figurines / toys, engineers 3D printed a model of the Maiwand Lion statue in Forbury Garden, Reading, UK.

All settings for this print on the Snapmaker 3D printer stayed the same as for the calibration tests in order to save time during the print as this was selected as a fast prototype / toy. Due to the layer height of 0.2 mm and the size of the model of approx. 650 mm x 250 mm x 350 mm, there are noticeable burrs in the finished lion. Over time, of course, the lion could also be 3D printed with a layer height of 0.1mm for a smoother finish. Despite the ridges, the lion maintains a strong shape.

Maiwand Lion 3D printed in Amazon Basics black PLA. Photo from the 3D printing industryMaiwand Lion 3D printed in Amazon Basics black PLA. Photo from the 3D printing industry

In a second functional test, a wheel was 3D printed in red PETG (layer height 0.2 mm). Slight chaining is observed in photos between the spokes of the wheel and the rim has a smooth surface suitable for adding a tire.

A wheel made of red PETG filament from Amazon Basics. Photo from the 3D printing industryA wheel made of red PETG filament from Amazon Basics. Photo from the 3D printing industry

Amazon Basics Filament – final thoughts

The team’s final verdict is that both Amazon Basics PLA and PETG produce good quality 3D prints and are easy to work with. Other online reviews had found an inconsistent color with the red filament, but no such error was found in this report.

At a single price of $ 19 per 1kg spool, engineers also noted the value for money of the material, especially given the superior processing of PETG. One final seal of approval was that an engineer in the 3D printing industry said he would buy the material for his personal work.

Print settings for checking the Amazon Basics filaments

Snapmaker Wanhao Duplicator 9
Slicer Snapmakerjs 2.4.3 Simplify 3.1.0
Layer height 0.2 mm (calibration tests, Lion)

0.1 mm (Pietà)
To fill 15% 10%
Print speed 40 mm / s 50 mm / s
PLA bed temperature 50 ° C. 60 ° C.
PLA printing temperature 200 ° C. 215 ° C.
PETG bed temperature 80 ° C. 70 ° C.
PETG printing temperature 235 ° C. 240 °

For more exclusive news and reviews, subscribe to the 3D Printing Industry Newsletter, find us on Facebook and like us on Twitter. Looking for engineering jobs? Find vacancies and apply using 3D printing jobs. You can also create a profile to promote your latest job openings.

The image shown shows a series of test prints made from Amazon Basics filament. Photo from the 3D printing industry

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ABS 3D printing filament
18 Dec
Blog

3D Printing Filament Information: ABS Filament

As the manufacturing industry is democratized by 3D printing, the technology is also being studied, researched, tested and used by people from different industries. The technology is not limited to engineers, but designers, hobbyists, and enthusiasts also use technology and building products.

As this technology is also used by numerous non-technical users, we are seeing a high failure rate and this creates a false impression of the 3D printing technology.

In this 3D Printing Filament Guide, we are going to explain how to be successful in 3D printing with the dreaded ABS filament. This will help users in 3D printing by taking the necessary precautions and will contribute to greater success in 3D printing.

What is ABS filament?

Above: ABS 3D printing filament / Photo credit: Matterhackers

ABS stands for acrylonitrile butadiene styrene, a thermoplastic polymer. Because it is thermoplastic, it can be heated to its melting point, cooled, and reheated without significant degradation. As a result, these are widely used and mainly used in the plastics industry through injection molding.

ABS is not a naturally occurring material. It is made by an emulsion process. It is also made through a patented process called continuous bulk polymerization.

Why is ABS so popular?

ABS 3D printing filamentAbove: Lego bricks are made of ABS plastic / Photo credit: Lego

ABS is widely used in many plastic applications such as dashboards, LEGO parts, computer keyboards, housings and cases, etc. The reason for such wide use lies in the fact that it has excellent mechanical properties. It is easy to work with and has a low melting point which helps in injection molding into various products. In addition, it is relatively inexpensive.

3D printing filament manual: properties of ABS filament

In this guide to the 3D printing filament, the properties of the ABS filament are now listed.

Superior mechanical properties: The ABS material is known for its high impact resistance. It is very sturdy and durable. In addition, it has high heat and chemical resistance, which makes it ideal for many industrial environments.

Easy to edit: ABS filaments are quite easy to rework. In fact, this is also one of the main reasons why ABS filaments are preferred over other materials. It can easily be glued, painted and sanded. Acetone fumes can be used to give the parts a shiny finish.

Inexpensive: ABS material is relatively inexpensive and easily available in almost all major regions of the world. The price is comparable to polypropylene (PP) and / or polycarbonate (PC).

3D Printing Filament Guide: Understanding ABS Filament

ABS is a natural choice of parts manufacturers because of its inherent properties and existing uses in various industries. ABS is therefore also used extensively in 3D printing. In addition, ABS can easily be reworked as required. This makes it an optimal material for prototyping and even for end use through 3D printing.

Careful reworking of the ABS part can achieve an even, high-gloss finish. This makes it an ideal choice for all types of prototypes. One of the well-known uses of 3D printed ABS is in housings for IoT devices.

ABS is a non-biodegradable filament that cannot be fully recycled. ABS filament is toxic, but not with 3D printing. Above 400 ° C, the material breaks down into acrylonitrile, butadiene and styrene, all of which can have carcinogenic effects on humans. Therefore, as a precaution, it is always recommended to wear appropriate masks when printing with ABS

Many manufacturers of 3D printing filaments supply ABS filaments. In India, companies like Rever Industries and Solidspace Technologies are some of the providers.

Price for ABS filament

ABS filaments generally cost between $ 15 and $ 70 per kilogram

In India, ABS filament would cost around Rs. 1000-1200 per kilogram

3D printing with ABS filament

ABS 3D printing filamentAbove: A cracked part made of ABS filament / Photo credit: Rigid.ink

While everything looks good with 3D printing, the material has a certain level of difficulty in printing. Many users experience problems with distortions, cracks, and inaccuracies. This results in people having a negative perception of the material.

First, it is important to understand that there is no common setting for all 3D printing filaments. Once we fathom this reality, we can work with different settings for different filaments and achieve excellent printing results.

ABS doesn’t print like PLA. It is far more complex than a normal PLA material. Many settings play a role in 3D printing with ABS filaments. It is recommended that users understand the possible causes of failure before switching to 3D printing ABS.

We’ll first take a look at the general pressure settings for ABS filaments.

General print settings
Printing temperature: 200 ° C to 250 ° C.
Bed temperature: 90 ° C to 110 ° C.
Printing speed: 20-30 mm / s
Attachment: Recommended

Tips for 3D printing ABS filaments

In this 3D Printing Filament Guide, we are going to share some tips about 3D printing with ABS filament.

First layer adhesion: It is important that the first layer adhere to the bed. For this purpose, the bed can be heated to approx. 100 ° C. Additionally, Kapton tape, glue, or ABS slurry can be applied to the bed surface to increase the adhesion of the print.

Use bed adhesion tools: Always use bed adhesion tools like brim and rafts from the slicer settings so that bed adhesion can be ensured throughout the duration of the print.

Use within the manufacturer’s temperature range: Always use the ABS filament within the temperature range specified by the filament manufacturer. Different manufacturers have slightly different ideal temperature settings, so it is always recommended that you follow this reference.

Closed housing: A closed housing ensures that the bed temperature is not affected and the pressure is carried out in a controlled environment. This helps in avoiding layer cracks.

Switching off the fan: Turn off the fan while printing with ABS filament. This also helps ensure a successful print.

Slow initial layer speed: Use advanced slicer settings to set slow initial layer speeds and ensure better first layer adhesion.

Keep the filament dry: Always store ABS filaments in a dry place so that they do not absorb humidity. Moisture can significantly affect the 3D printing process.

It’s important to understand that FDM 3D printing takes a lot of trial and error, and it’s always great to experiment and tweak the print settings to get better print results. This 3D Printing Filament Guide is a resource for any new learner to achieve a successful print every time.

About Manufactur3D Magazine: Manufactur3D is an online 3D printing magazine that publishes the latest 3D printing news, insights, and analysis from around the world. You can find more informative articles on our 3D printing information page.

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Global 3D Printing Filament Market
18 Dec
Blog

In-Depth Report on 3D Printing Filament Market Growth Projected to Achieve an Uptick Throughout 2020-2027

A new informative report entitled “Global 3D Printing Filament Market” was recently published in the extensive repository of Contrive Market Research. Research on 3D printing filaments around the world is often traced back to several applicable business strategies to expand the business. In addition, it provides a comparative study of the key players along with their business frameworks to understand the global competition between them. It provides a complete analysis of market strategies and how these strategic forces affect market growth. Due to the increasing demand for online platforms in companies, it offers technological advances and their effects on companies. In addition, it offers insights into changing business scenarios, historical records, and futuristic developments.

Sample Copy of Reports: https://contrivemarketresearch.com/sample_request/5615

The main actors covered in this study: Stratasys Ltd. (USA), 3D Systems Corporation (USA), Koninklijke DSM NV (Netherlands), Materialize NV (Belgium), Evonik Industries AG (Germany), Arkema SA (France), Saudi Basic Industries Corporation (SABIC) (Saudi Arabia)) , DuPont de Nemours, Inc. (USA), BASF 3D Printing Solutions GmbH (Germany), HP Inc. (USA), EOS GmbH – Elektrooptische Systeme (Germany), Shenzhen Esun Industrial Co., Ltd. (China), CRP Technology Srl (Italy), EnvisionTEC GmbH (Germany), Oxford Performance Materials, Inc. (USA) and MG Chemicals (Canada), among others

The report also describes the sales and revenue of the global 3D Printing Filament Market. It is divided into many segments, e.g. B. at regional, country level, by type, application and others. This allows for a detailed view of the market and focuses on government policies that could change the dynamics. It also evaluates companies’ research and development plans for better product innovation.

The report provides a comprehensive look at the competitive landscape of the global 3D Printing Filament Market, along with the detailed business profiles of the major market players. The analysts in the report measure threats and weaknesses to leading companies using industry-standard tools such as Porter’s Five Forces Analysis and SWOT Analysis. The 3D Printing Filaments market report covers all the key parameters such as product innovation, market strategy for leading companies, 3D printing filament market share, revenue generation, latest research and development results, and market expert perspective.

Global 3D Printing Filament Market Segmentation:

On the basis of type :, plastics by material, ABS, PLA, TPE, PA, photopolymers, others (PC, PS, PVA, PEEK, PAEK, PEKK and ULTEM), metals by material, titanium, aluminum, stainless steel, nickel , others (copper, gold, silver, bronze and cobalt chrome), ceramics, by material, glass, quartz glass, quartz, others (zirconium oxide, graphite, clay and aluminum oxide), others (wax, wood and paper)

Based on Application: Aerospace & Defense, Medicine & Dental, Automotive, Electronics, Others (Fashion, Consumer Goods, Education, Art & Sculpture, Jewelry & Architecture)

Get special discount: https://contrivemarketresearch.com/check-discount/5615

In order to determine the market needs in the global regions, an analytical survey was conducted in North America, Latin America, Africa, Europe and Asia-Pacific for a clear idea. The global market for 3D printing filaments has the highest market share in the region. The Asia Pacific region has a large population, which makes its market potential significant. It is the fastest growing and most lucrative region in the world economy. This chapter specifically explains the population impact on the global 3D Printing Filament Market. The research looks at it through a regional lens, giving readers a microscopic understanding of the changes they need to prepare for.

This research report also includes:

– Analysis of established and new market participants

-Finance Management

-Strategic planning of business resources

-Various case studies and hands-on development by C-level professionals

-Applicable tools, methods and standard operating procedures

-Global market forecast

-A detailed elaboration of market segments and sub-segments

-Various risks, challenges, threats and weaknesses in front of the market

– Approaches to discovering global opportunities, customers and potential customers.

Table of contents (TOC):

Part 1 market overview

1.1 Market definition

1.2 Market development

1.3 By type

1.4 Upon request

1.5 By region

Part 2 key companies

Part 3 Global Market Status and Future Forecast

3.1 Global Market by Regions

3.2 Global Market by Company

3.3 Global Market by Type

3.4 Global Market by Application

3.5 Global market according to forecast

Part 4 Asia-Pacific Market Status and Future Forecast

4.1 Asia-Pacific Market by Type

4.2 Asia Pacific Market by Application

4.3 Asia-Pacific Market By Geography

4.3.1 China market status and future forecast

4.3.2 Market status and future forecast for Southeast Asia

4.3.3 Market status and future forecast for India

4.3.4 Japan Market Status and Future Forecast

4.3.5 Korea market status and future forecast

4.3.6 Oceania Market Status and Future Forecast

4.4 Asia-Pacific market according to forecast

Part 5 Market Status and Future Forecast for Europe

5.1 European market by type

5.2 European market according to application

5.3 European market by geography

5.3.1 Germany market status and future forecast

5.3.2 Market status and future forecast for Great Britain

5.3.3 Market status and future forecast for France

5.3.4 Italy market status and future forecast

5.3.5 Russia market status and future forecast

5.3.6 Spain market status and future forecast

5.3.6 Dutch market status and future forecast

5.3.7 Turkey’s market status and future forecast

5.3.6 Swiss market status and future forecast

5.4 European market according to forecast

Part 6 North America Market Status and Future Prospects

6.1 North America Market by Type

6.2 North American Market by Application

6.3 North American Market by Regions

6.3.1 US Market Status and Future Prospects

6.3.2 Canadian Market Status and Future Prospects

6.3.3 Market Status in Mexico and Future Prospects

6.4 North American market according to forecast

Part 7. South American Market Status and Future Prospects

7.1 South American Market by Type

7.2 South American Market by Application

7.3 South American market

7.3.1 Market Status and Future Prospects for Brazil

7.3.2 Argentina’s market status and future prospects

7.3.3 Columbia Market Status and Future Forecast

7.3.4 Market Status and Future Prospects in Chile

7.3.5 Market Status in Peru and Future Prospects

7.4 South American market forecast

Part 8 Middle East and Africa market status and future prospects

8.1 Middle East and Africa Market by Type

8.2 Middle East and Africa Market By Application

8.3 Middle East and Africa Markets by Region

8.3.1 GCC Market Status and Future Prospects

8.3.2 Market Status and Future Prospects for North Africa

8.3.3 Market status and future forecast for South Africa

8.4 Middle East and Africa Market Forecasts

Part 9 market characteristics

9.1 Product features

9.2 Price features

9.3 Channel functions

9.4 Purchasing functions

Part 10 investment opportunity

10.1 Regional investment opportunity

10.2 Investment Opportunity for Industry

Part 11 conclusion

2020 by product segment, technology, application, end-user, future opportunities and region by 2027

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