Yourtech Services

Yourtech Services are sales and service agents for many of the industry leaders in our field including KONICA MINOLTA Copiers and Printers, Brother and HP Printers along with Zortrax, Makerbot and UP 3D Printers as well as offering BENQ Interactive boards for schools and boardrooms.

3D Printed Wearable Market Size, Share, Trends, Key Drivers, Growth Opportunities and Competitive Outlook

Data Bridge Market research has recently issued comprehensive industry research on Global 3D Printed Wearable Market which includes growth analysis, regional marketing, challenges, opportunities, and drivers analysed in the report. The market insights gained through this 3D Printed Wearable market research analysis report facilitates more defined understanding of the market landscape, issues that may interrupt in the future, and ways to position definite brand excellently.

An analysis of competitors is conducted very well in the reliable 3D Printed Wearable Market report which covers vital market aspects about the key players. Moreover, the report gives out market potential for many regions across the globe based on the growth rate, macroeconomic parameters, consumer buying patterns, their preferences for particular product and market demand and supply scenarios. It gives significant information and data pertaining to their insights in terms of finances, product portfolios, investment plans, and marketing and business strategies. Detailed market analysis has been performed here with the inputs from industry experts.

3D Printed Wearable Market: Convenience Goes Smart Market, By Product Type (Clothes, Watches, Footwear, Jewellery, Accessories and Other Miscellaneous Products), Price (Premium and Mass), Consumer Orientation (Men, Women, Children and Unisex), Distribution Channel (Online and Offline), Country (U.S., Canada, Mexico, Brazil, Argentina, Rest of South America, Germany, France, Italy, U.K., Belgium, Spain, Russia, Turkey, Netherlands, Switzerland, Rest of Europe, Japan, China, India, South Korea, Australia, Singapore, Malaysia, Thailand, Indonesia, Philippines, Rest of Asia-Pacific, U.A.E, Saudi Arabia, Egypt, South Africa, Israel, Rest of Middle East and Africa) Industry Trends and Forecast to 2028

Access Full 350 Pages PDF Report @

Highlights of TOC:

Chapter 1: Market overview

Chapter 2: Global 3D Printed Wearable Market

Chapter 3: Regional analysis of the Global 3D Printed Wearable Market industry

Chapter 4: 3D Printed Wearable Market segmentation based on types and applications

Chapter 5: Revenue analysis based on types and applications

Chapter 6: Market share

Chapter 7: Competitive Landscape

Chapter 8: Drivers, Restraints, Challenges, and Opportunities

Chapter 9: Gross Margin and Price Analysis

Key Questions Answered with this Study

1) What makes 3D Printed Wearable Market feasible for long term investment?

2) Know value chain areas where players can create value?

3) Teritorry that may see steep rise in CAGR & Y-O-Y growth?

4) What geographic region would have better demand for product/services?

5) What opportunity emerging territory would offer to established and new entrants in 3D Printed Wearable Market?

6) Risk side analysis connected with service providers?

7) How influencing factors driving the demand of 3D Printed Wearablein next few years?

8) What is the impact analysis of various factors in the Global 3D Printed Wearable Market growth?

9) What strategies of big players help them acquire share in mature market?

10) How Technology and Customer-Centric Innovation is bringing big Change in 3D Printed Wearable Market?

The major players covered in the 3D printed wearable market: convenience goes smart report are SAMSUNG, Garmin Ltd., Huawei Technologies Co., Ltd., Apple Inc., Sony Corporation, HTC Corporation, Fitbit, Inc., Xiaomi Global Community, ADIDAS AG, Nike, Inc., New Balance, MakerBot Industries, LLC, makerarm.com, LG Electronics., Motorola Solutions, Inc., Fossil Group, Inc., Google LLC, Polar Electro, Withings, Michael Kors, CASIO AMERICA, INC., TomTom International BV. and Under Armour, Inc. among other domestic and global players. Market share data is available for Global, North America, Europe, Asia Pacific (APAC), Middle East and Africa (MEA) and South America separately. DBMR analysts understand competitive strengths and provide competitive analysis for each competitor separately.

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Data Bridge set forth itself as an unconventional and neoteric Market research and consulting firm with unparalleled level of resilience and integrated approaches. We are determined to unearth the best market opportunities and foster efficient information for your business to thrive in the market. Data Bridge endeavors to provide appropriate solutions to the complex business challenges and initiates an effortless decision-making process.

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Creating a top 10 list of 3D printers for 2024 without including resin printers requires focusing on the variety and advancements within the Fused Deposition Modeling (FDM) market and beyond. This list will cater to a range of needs, from hobbyist and educational use to professional and industrial applications. Here are the top 10 FDM 3D printers of 2024, based on their performance, features, user reviews, and innovation:

Top 10 3D Printers of 2024

1. Ultimaker S5 Pro Bundle

Ideal for: Professionals and industries

Features: Dual extrusion, air manager, material station, high reliability

2. Prusa i3 MK4

Ideal for: Hobbyists, educators, and professionals

Features: Open-source, auto-calibration, speed, noise reduction

3. Creality Ender-6

Ideal for: Hobbyists and small businesses

Features: Semi-enclosed chamber, core-XY structure, great value

4. MakerBot Method X Carbon Fiber Edition

Ideal for: Industrial applications

Features: Carbon fiber reinforcement, heated chamber, precision extruders

5. LulzBot TAZ Pro

Ideal for: Professionals seeking versatility

Features: Dual extrusion, large build volume, high print quality

6. FlashForge Creator Pro 2

Ideal for: Beginners and educators

Features: Independent dual extruders, reliability, affordability

7. BCN3D Epsilon W50

Ideal for: Professional and industrial use

Features: Large build volume, dual extrusion, industrial-grade parts

8. Anet A8 Plus

Ideal for: Budget-conscious hobbyists

Features: Large build volume, upgradable, affordable

9. Dremel DigiLab 3D45

Ideal for: Educators and professionals

Features: High reliability, easy to use, great support materials

10. Sindoh 3DWOX 1

Ideal for: Office and educational settings

Features: Enclosed build chamber, low noise, cartridge filament system

Choosing the Right 3D Printer

Selecting the right 3D printer from this list depends on several factors:

Purpose and Application: Whether for hobbyist, educational, or industrial purposes, choose a printer that aligns with your primary needs.

Build Volume: Consider the size of the prints you plan to make. Larger build volumes offer more flexibility for projects.

Material Compatibility: Depending on your projects, ensure the printer supports the materials you intend to use, including specialty filaments for industrial applications.

Ease of Use: For beginners and educational settings, user-friendly interfaces and reliable customer support are key.

Budget: Prices vary widely, from affordable models for hobbyists to more expensive, professional-grade printers. Balance cost with the features and quality you need.

Conclusion

The 3D printing landscape in 2024 is diverse, offering something for everyone, from beginners to advanced users. The top 10 FDM 3D printers listed above represent the pinnacle of current technology, showcasing the advancements that make 3D printing more accessible, versatile, and capable than ever before. Whether you're a hobbyist looking to bring your ideas to life, an educator shaping the next generation of makers, or a professional manufacturing prototypes, there's a 3D printer out there to meet your needs.

The Next Frontier: How 3D Printing is Revolutionizing Manufacturing - Technology Org

New Post has been published on https://thedigitalinsider.com/the-next-frontier-how-3d-printing-is-revolutionizing-manufacturing-technology-org/

The Next Frontier: How 3D Printing is Revolutionizing Manufacturing - Technology Org

3D printing, also known as additive manufacturing, has gained significant popularity in recent years, revolutionizing the manufacturing industry. The concept of 3D printing dates back to the 1980s when it was first introduced as a rapid prototyping technology. However, it is only in the past decade that 3D printing has gained widespread recognition and adoption in various industries.

The growing popularity of 3D printing can be attributed to its ability to create complex and customized objects with ease. Traditional manufacturing methods often involve multiple steps and processes, which can be time-consuming and costly. 3D printing simplifies the manufacturing process by directly creating objects layer by layer from a digital design, eliminating the need for molds or tooling.

The central piece of a 3D printer – illustrative photo. Image credit: Christian Englmeier via Unsplash, free license

The History of 3D Pringting

The concept of additive manufacturing has existed since the 1940s. In 1945, sci-fi author Murray Leinster described a machine that could “make drawings in the air” and output plastic parts layer-by-layer in his short story “A Logic Named Joe.” However, it took a few more decades for this vision to become reality.

1980s: Early Prototyping

In 1981, Dr. Hideo Kodama of Nagoya Municipal Industrial Research Institute invented one of the first working rapid prototyping systems. It used photopolymers that could be cured by UV light to build parts additively.

In 1984, Charles “Chuck” Hull filed a patent for stereolithography (SLA), which described an additive manufacturing process using photopolymers cured layer-by-layer by UV lasers. He later co-founded the company 3D Systems to commercialize SLA 3D printers.

In 1986, Carl Deckard, an undergraduate at the University of Texas, filed a patent for selective laser sintering (SLS), another 3D printing process that used a laser to fuse powder material. Deckard’s patent was licensed by DTM corporation, which released the Sinterstation 2000, the first SLS machine, in 1992.

In 1989, S. Scott Crump invented fused deposition modeling (FDM) and patented the technology. This process used a heated nozzle to extrude thermoplastic filament material layer by layer. Crump later commercialized it through the company Stratasys, which he co-founded.

1990s: Industry Growth

In 1992, 3D Systems released the SLA-250, which was the first commercially available 3D printer. Meanwhile, Stratasys introduced their first commercial FDM 3D printer in 1992 as well.

Through the 1990s and 2000s, the industry saw rising adoption and usage of additive manufacturing for rapid prototyping across automotive, aerospace, medical, consumer goods and other industries. Both established corporations and startups expanded the capabilities of 3D printing during this period.

2000s: Patent Expiration, Desktop 3D Printers

A significant milestone came in 2009 when key SLA patents expired, opening up the technology. This allowed for the rise of desktop SLA 3D printers like the Form 1, developed by startup Formlabs in 2012.

The expiration of FDM patents around 2010 similarly saw a wave of open source FDM/FFF desktop 3D printers like the RepRap, inspiring companies like MakerBot. This drove increased adoption of desktop 3D printing.

The Basics of 3D Printing: How it Works and its Advantages

The process of 3D printing involves several steps. First, a digital design of the object is created using computer-aided design (CAD) software. This design is then converted into a format that can be read by the 3D printer. The printer then builds the object layer by layer using various materials such as plastic, metal, or even biological materials.

One of the key advantages of 3D printing is its ability to create complex geometries that are difficult or impossible to achieve with traditional manufacturing methods. Traditional methods often involve subtractive processes, where material is removed from a larger block to create the desired shape. In contrast, 3D printing is an additive process, where material is added layer by layer to create the final object.

Another advantage of 3D printing is its ability to create customized products. With traditional manufacturing methods, producing customized products can be expensive and time-consuming. However, with 3D printing, each object can be easily customized by simply modifying the digital design before printing.

From Prototyping to Production: How 3D Printing is Changing the Manufacturing Process

One of the key roles of 3D printing in manufacturing is in the prototyping stage. Traditionally, prototyping involved creating molds or tooling, which can be expensive and time-consuming. With 3D printing, prototypes can be created quickly and cost-effectively, allowing for faster iteration and refinement of designs.

However, 3D printing is not limited to prototyping alone. It has the potential to replace traditional manufacturing methods in certain applications. For example, in industries such as aerospace and automotive, where complex geometries are often required, 3D printing can offer significant advantages over traditional methods. By eliminating the need for molds or tooling, 3D printing can reduce costs and lead times while enabling the production of lightweight and optimized components.

Customization and Personalization: The Power of 3D Printing in Meeting Customer Demands

One of the key advantages of 3D printing is its ability to create customized products. Traditional manufacturing methods often involve producing large quantities of identical products, which may not meet the specific needs or preferences of individual customers. With 3D printing, each product can be easily customized to meet the unique requirements of each customer.

This ability to create customized products has a significant impact on the customer experience. Customers today are increasingly looking for personalized products that reflect their individual tastes and preferences. By offering customized products, companies can differentiate themselves from their competitors and build stronger relationships with their customers.

Reducing Costs and Waste: The Economic Benefits of 3D Printing in Manufacturing

One of the key advantages of 3D printing is its potential to reduce manufacturing costs. Traditional manufacturing methods often involve multiple steps and processes, each adding to the overall cost of production. In contrast, 3D printing simplifies the manufacturing process by directly creating objects from a digital design, eliminating the need for molds or tooling.

By reducing the number of steps and processes involved in manufacturing, 3D printing can significantly reduce costs. This is particularly beneficial for small and medium-sized enterprises (SMEs) that may not have the resources to invest in expensive molds or tooling. With 3D printing, SMEs can compete with larger companies by offering customized products at a lower cost.

In addition to reducing costs, 3D printing also has the potential to reduce waste. Traditional manufacturing methods often result in significant material waste, as excess material is removed during the production process. With 3D printing, only the required amount of material is used, minimizing waste and reducing environmental impact.

Sustainability and Environmental Impact: How 3D Printing is Helping to Reduce Carbon Footprint

In addition to reducing waste, 3D printing also has the potential to reduce carbon footprint. Traditional manufacturing methods often involve transporting raw materials and finished products over long distances, resulting in significant carbon emissions. With 3D printing, products can be manufactured locally, reducing the need for transportation and lowering carbon emissions.

Furthermore, 3D printing enables the use of more sustainable materials. For example, bio-based materials can be used in 3D printing, reducing reliance on fossil fuels and minimizing environmental impact. Additionally, 3D printing allows for the optimization of designs, resulting in lighter and more efficient products that require less energy to produce and use.

The Role of 3D Printing in Industry

The impact of 3D printing on various industries is significant. In the healthcare industry, 3D printing has revolutionized medical device manufacturing by enabling the production of customized implants and prosthetics. In the aerospace industry, 3D printing has been used to create lightweight components that improve fuel efficiency and reduce emissions.

The potential for 3D printing to disrupt traditional manufacturing industries is also significant. For example, in the automotive industry, 3D printing has the potential to transform the production of spare parts. Instead of maintaining large inventories of spare parts, manufacturers can simply 3D print the required parts on demand, reducing costs and lead times.

The Future of Manufacturing

The potential for 3D printing to revolutionize the manufacturing industry is immense. As the technology continues to evolve and improve, we can expect to see even greater adoption of 3D printing in various industries. The ability to create complex and customized objects with ease will continue to drive the growth of 3D printing in manufacturing.

However, there are also challenges and opportunities associated with 3D printing in manufacturing. One of the key challenges is the need for skilled operators who can design and operate 3D printers effectively. Additionally, there are regulatory challenges that need to be addressed, particularly in industries such as healthcare where safety and quality standards are critical.

The Challenges of 3D Printing in Manufacturing: Overcoming Technical and Regulatory Hurdles

One of the key technical challenges of 3D printing in manufacturing is the limited range of materials that can be used. While 3D printing has made significant advancements in recent years, there are still limitations in terms of the types of materials that can be used. For example, metals such as titanium and aluminum are commonly used in traditional manufacturing methods but are more challenging to 3D print.

Another technical challenge is the need for post-processing and finishing. While 3D printing can create complex geometries with ease, the surface finish of 3D printed objects is often rough and requires additional processing to achieve the desired quality. This can add time and cost to the manufacturing process.

In addition to technical challenges, there are also regulatory challenges associated with 3D printing in manufacturing. In industries such as healthcare, where safety and quality standards are critical, there is a need for regulatory frameworks to ensure that 3D printed products meet the required standards. This includes the need for validation and certification processes to ensure the safety and efficacy of 3D printed medical devices.

The Impact of 3D Printing on Supply Chain Management: Opportunities and Challenges

The potential for 3D printing to disrupt supply chain management is significant. With traditional manufacturing methods, products are often manufactured in one location and then transported to various distribution centers or retail stores. This can result in long lead times and high transportation costs.

With 3D printing, products can be manufactured locally, reducing the need for transportation and lowering lead times. This has the potential to transform supply chain management by enabling companies to produce products on demand, reducing inventory costs and improving responsiveness to customer demands.

However, integrating 3D printing into supply chain management also presents challenges. For example, companies will need to invest in 3D printing infrastructure and develop new processes and workflows to support on-demand manufacturing. Additionally, there may be challenges in terms of intellectual property protection and ensuring product quality and consistency across different manufacturing locations.

The Future of 3D Printing in Manufacturing: Emerging Trends and Technologies

The future of 3D printing in manufacturing is promising, with several emerging trends and technologies driving its growth. One of the key trends is the development of new materials that can be used in 3D printing. Researchers are exploring the use of materials such as graphene, carbon fiber, and biodegradable polymers, which offer improved strength, durability, and sustainability.

Another emerging trend is the development of multi-material and multi-color 3D printing technologies. Currently, most 3D printers can only print objects using a single material or color. However, researchers are working on developing printers that can print objects using multiple materials or colors simultaneously, opening up new possibilities for complex and customized designs.

The Promise of 3D Printing in Revolutionizing Manufacturing

3D printing has the potential to revolutionize the manufacturing industry. Its ability to create complex and customized objects with ease, reduce costs and waste, and promote sustainability makes it an attractive option for manufacturers across various industries.

While there are challenges and opportunities associated with 3D printing in manufacturing, the promise of this technology is immense. As the technology continues to evolve and improve, we can expect to see even greater adoption of 3D printing in manufacturing, leading to a more efficient, sustainable, and customer-centric manufacturing industry.

3D printing is transforming manufacturing across industries in revolutionary ways. Its ability to rapidly prototype designs, create complex geometries, enable mass customization, reduce waste, and distribute production is disrupting traditional processes. Companies are adopting 3D printing to accelerate product development, unlock new design possibilities, produce specialized components, and manufacture goods on-demand. While the technology does have some limitations currently, advancements around speed, materials, and costs are helping address these.

Overall, 3D printing provides unmatched flexibility that is spurring a manufacturing revolution. It allows for more sustainable production methods with less waste and emissions. As the capabilities of 3D printing continue to advance, its applications will expand even further. Forward-thinking companies that leverage this technology now will gain key competitive advantages. Adoption is still in early phases, signaling immense room for growth. 3D printing is undoubtedly redefining manufacturing as we know it and enabling the factories of the future.

3D Printer : A Upcoming regarding Development

Introduction The latest technology known as 3D printing has definitely been heard about by everyone. This is one of the most exciting contemporary technologies. You must be acquainted with typical 2D printers, which can only print in two dimensions using ink. So, according to this simple analogy, if you correctly identified your answer as "ahaa, as it prints in the third dimension it is named a "3D printer," you did well! For instance, using titanium, liquid resins for dental purposes, powdered aluminum, and partially molten plastic to make toys. Increasingly more people are using 3D printers throughout time. Even institutions like Tesla, NASA, and the British Museum use desktop 3D printers due to their high popularity. Nike and the Indian rocket maker Agnikul both use 3D printing to make the soles of their shoes and rocket engines, respectively. Despite using various techniques, most 3D printing systems adhere to the same fundamental concept. Before a printer starts printing the item, the digital design of any object is split into hundreds of layers, with each layer often being the size of a sheet of paper. A physical item is produced by the printer using the entire stack of layers after each layer has been printed one by one.

Major Features

The market is filled with various 3D printers. As we've already noted, 3D printers can use an abundance of strategies, but the most common ones are Fused Deposition Modelling (FDM) and Stereo Lithography Apparatus (SLA). Prusa, Makerbot, Creality, Ultimaker, FormLabs, and many other brands are popular names in the 3D printing industry. Additionally, you don't need to purchase one to print as there are online 3D printing services.

Price: $299 USD

The following features are available:

Titan extruder and modular nozzle set

Automatic bed leveling

Resume print function

Integrated cable design

Description: The Sidewinder X2 continues to have a sizeable construction volume of 300 x 300 x 400 mm. This 3D printer's Titan extruder includes a volcano nozzle that is modular. The machine now extrudes more rapidly and offers high-precision printing in addition to the filament and power loss detection, an AC fast-heating print bed, and compact flat cabling that were praised features of its predecessor. The Artillery Sidewinder X2 3D Printer had a strong market entry. It did so because it met the industry's stringent standards for release. Materials of a 1.75 mm diameter, including PLA, ABS, flexible PLA, TPU, and wood, can be printed on using the Artillery Sidewinder X2. Eventually, 3D printing might displace traditional industrial processes. It is currently easier to build complex designs that previously seemed difficult to make. Significant applications of additive manufacturing have also been observed in the realm of medicine. When the right tissue engineering techniques are applied, it is possible to print an entire organ. But it hasn't yet been able to create an organ that is fully functional. Nevertheless, sooner or later, we might see a printed prosthetic heart! If 3D printing can accomplish this, many lives could be saved. In spite of what it might look like, 3D printers may eventually be used to print your favorite apparel, footwear, jewelry, or even presents for your loved ones.

Bree Pettis: Pioneer in Tech Innovation and Entrepreneurship

Bree Pettis, an accomplished entrepreneur, is set to speak at Startup Iceland 2023, a gathering of entrepreneurs, investors, and thought leaders from around the world. Pettis is widely recognized as a pioneer in the field of tech innovation and entrepreneurship, having co-founded MakerBot Industries and spearheaded the development of the DIY 3D printing movement. Pettis’ journey into the tech…

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Sie sind auf der Suche nach neuen Ideen für Ihre 3D-Druck-Projekte? Sie möchten Ihre eigenen Designs mit anderen teilen und Feedback erhalten? Sie interessieren sich für Open-Source-Hardware und die Maker-Bewegung? Dann sollten Sie Thingiverse kennen lernen. Thingiverse ist eine Online-Plattform, die sich dem Teilen von digitalen Design-Dateien widmet. Die meisten Dateien sind kostenlos und unter der GNU General Public License oder Creative Commons-Lizenzen veröffentlicht. Die Nutzer können die Dateien mit 3D-Druckern, Laserschneidern oder CNC-Maschinen physisch erstellen oder bei 3D Druck München einfach drucken und sich liefern lassen. In diesem Blogbeitrag erfahren Sie mehr über die Geschichte und die Funktionen von Thingiverse und wie Sie davon profitieren können.   Die Geschichte von Thingiverse Thingiverse wurde im November 2008 von Zach Smith als Begleitseite zu MakerBot Industries gegründet, einem Unternehmen für DIY-3D-Drucker-Kits. Im Jahr 2013 wurden Makerbot und Thingiverse von Stratasys übernommen. Der Open-Source-Wert von Thingiverse war ein wichtiger Bestandteil im Wert von Makerbot. Thingiverse erhielt eine lobende Erwähnung in der Kategorie Digital Communities des internationalen Wettbewerbs für Cyber-Arts ARS Electronica | Prix Ars Electronica 2010. Bis November 2012 waren mehr als 25.000 Designs auf Thingiverse hochgeladen worden; bis Juni 2013 überschritt die Gesamtzahl 100.000. Das 400.000ste Ding wurde am 19. Juli 2014 veröffentlicht. Viele der Designs auf Thingiverse sind für das Gemeinwohl gedacht - z.B. assistive Technologien. Die Website gehört Ultimaker und wurde ursprünglich von MakerBot Industries besessen und von einem seiner Gründer, Bre Pettis, in Brooklyn, New York betrieben . In ihren Nutzungsbedingungen legt Thingiverse fest, dass Nutzer keine Inhalte einschließen dürfen, die “zur Erstellung von Waffen, illegalen Materialien oder anderweitig anstößig sind”. Thingiverse ist eine der größten und beliebtesten Plattformen für digitale Designs im Internet und hat eine treue und aktive Community aufgebaut.   Die Funktionen von Thingiverse Thingiverse bietet eine Reihe von Funktionen an, um das Teilen und Entdecken von digitalen Designs zu erleichtern und zu fördern. Hier sind einige davon: Kategorien: Die Nutzer können aus verschiedenen Kategorien wählen, um nach passenden Designs zu suchen oder ihre eigenen hochzuladen. Zu den Kategorien gehören z.B. Kunst, Mode, Gadgets, Hobby oder Lernen. Tags: Die Nutzer können ihre Designs mit Schlagworten versehen oder nach Schlagworten suchen, um ähnliche oder verwandte Designs zu finden. Sammlungen: Die Nutzer können ihre eigenen Sammlungen erstellen oder andere Sammlungen durchsuchen oder abonnieren, um thematisch zusammenhängende Designs zu organisieren oder zu entdecken. Likes: Die Nutzer können ihre Anerkennung für ein Design ausdrücken oder sehen, wie viele andere Nutzer ein Design mögen. Kommentare: Die Nutzer können Feedback geben oder erhalten, Fragen stellen oder beantworten, oder Diskussionen führen über ein Design. Remixes: Die Nutzer können ein bestehendes Design modifizieren oder verbessern und es als Remix hochladen, um ihre Kreativität zu zeigen oder zur Verbesserung der Community beizutragen. Apps: Die Nutzer können verschiedene Apps nutzen, um ihre Designs zu bearbeiten, zu personalisieren, zu drucken oder zu teilen.   Wie Sie von Thingiverse profitieren können Thingiverse ist nicht nur eine Datenbank für digitale Designs, sondern auch eine Plattform für kreative Köpfe. Sie können von Thingiverse profitieren, indem Sie: Inspiration finden: Sie können sich von den tausenden von Designs auf Thingiverse inspirieren lassen und neue Ideen für Ihre eigenen Projekte bekommen. Sie können auch nach Kategorien oder Tags filtern, um Designs zu finden, die Ihren Interessen oder Bedürfnissen entsprechen. Wissen teilen: Sie können Ihre eigenen Designs auf Thingiverse hochladen und der Community zur Ver

fügung stellen. Sie können auch Ihre Erfahrungen, Tipps oder Ratschläge mit anderen Nutzern teilen und Feedback erhalten. Sie können auch von dem Wissen anderer Nutzer profitieren und lernen, wie Sie Ihre Designs verbessern oder optimieren können. Kreativität ausdrücken: Sie können Ihre eigene Kreativität ausdrücken und Ihre Designs personalisieren oder remixen. Sie können auch verschiedene Apps nutzen, um Ihre Designs zu bearbeiten oder zu erweitern. Sie können auch an Wettbewerben oder Herausforderungen teilnehmen und Ihre Fähigkeiten unter Beweis stellen. Spaß haben: Sie können Spaß haben und sich mit anderen Nutzern austauschen oder vernetzen. Sie können auch spannende oder lustige Designs entdecken oder erstellen. Sie können auch Ihre fertigen Produkte zeigen oder bewundern.   Fazit Thingiverse ist eine Online-Plattform für digitale Designs, die es Ihnen ermöglicht, Ihre eigenen Kreationen zu teilen oder sich von anderen inspirieren zu lassen. Die Website bietet eine Vielzahl von Funktionen an, um das Teilen und Entdecken von Designs zu erleichtern und die Open-Source-Hardware-Community zu unterstützen. Wenn Sie sich für 3D-Druck, Laserschneiden oder CNC-Maschinen interessieren, sollten Sie Thingiverse einen Besuch abstatten und die tollen Möglichkeiten entdecken, die es Ihnen bietet. Und wenn Sie keine eigene Maschine haben, können Sie bei 3D Druck München einfach Ihr Wunschdesign drucken und sich liefern lassen.   [author] [author_image timthumb='on']https://3ddruckmuenchen.com/wp-content/uploads/2022/12/transparentes-rundes-Logo-von-3D-Druck-Muenchen.webp[/author_image] [author_info]Der Autor dieses Artikels ist 3D Druck München, Ihr kompetenter Partner für professionellen 3D-Druck mit deutschlandweitem Versand. Seit vielen Jahren sind wir im Bereich 3D-Druck tätig und verfügen über umfangreiche Erfahrung und Know-how. Unser Team besteht aus qualifizierten Ingenieuren, Designern und Technikern, die Ihnen individuelle Beratung, hochwertige Druckerzeugnisse und zuverlässigen Service bieten. Kontaktieren Sie uns gerne für ein unverbindliches Angebot.[/author_info] [/author]

Great 3D Printing Websites!

Tinkercad

“From Mind to Design in Minutes.” Tinkercad, Autodesk, https://www.tinkercad.com/.

This is the #1 place to get started on creating your own 3D models and learning about the process of 3D printing! Tinkercad has its own varied resources and lessons for introducing and cultivating 3D printing skills as well as providing a place to share designs with other printers!

Thingiverse

Thingiverse.com. “Digital Designs for Physical Objects.” Thingiverse, MakerBot Industries, https://www.thingiverse.com/.

A fantastic site for finding free 3D files that others around have decided to create and share! 3D modeling is rewarding but it can also be very time consuming. Sometimes there's not a need to reinvent the wheel if you can find one someone's already made and posted to Thingiverse!

Yeggi

“3D Printer Models Search Engine.” Yeggi, https://www.yeggi.com/.

Yeggi is another site that provides a wide variety of premade, ready to print 3D models! While Yeggi does not have some of the educational features of Thingiverse it still has a great deal of models. If you can't find something on Thingiverse then hop on over and search for it on Yeggi!

MeshLab

P. Cignoni, M. Callieri, M. Corsini, M. Dellepiane, F. Ganovelli, G. RanzugliaMeshLab: an Open-Source Mesh Processing Tool Sixth Eurographics Italian Chapter Conference, page 129-136, 2008

MeshLab is a software that is free to download that is a little more advanced of an editing tool than something like Tinkercad might have to offer. If any of the models found from other sites might have some issues MeshLab is a great place to fix them!

Image to Lithophane

3D Printing Rocks!, https://3dp.rocks/lithophane/.

Image to Lithophane is a really unique online tool that can turn some photos into 3D models! Functionally it's more similar to adding some tactile dimension to the picture rather than plucking out whole models from the scene but it is an interesting tool nonetheless!

3D printing is a revolutionary technology that's likely to have an enormous impact on the world. But what exactly is it? Table of Contents3D Printing-Whatchu Talkin' About?A Brief History of 3D PrintingTypes of 3D Printers3D printerFDM (fused deposition modeling)SLA (stereolithography)Open Source vs. Closed SourceSpeed of the Print ProcessCost of 3D PrintingWhere and How to Find Files to PrintFinal 3D Printing-Whatchu Talkin' About? 3D printing is the process of creating a three-dimensional object from a digital file. It's like printing out a document, except instead of ink being deposited onto paper, plastic or metal powder is laid down layer by layer to create an object with any shape or color you can imagine. 3D printing has been around for decades, but it was only in 2008 that it started to become mainstream. Today, there are more than 1,000 3D printers available for purchase and thousands more in development. A 3D printer essentially reads a digital file and creates a physical object based on that file. That digital file can be created by hand or created using software, such as a CAD (computer-aided design) program. The resulting object is a solid object made of plastic or metal, with the same properties as the materials it was printed from. So you can print an exact copy of something made out of wood or plastic. The idea behind 3D printing is simple: Take an object and convert it into a digital file (usually through CAD software). Then use that file to print out an exact replica of the original object using one of several methods: extrusion (basically squirting out melted plastic), laser sintering (melting together tiny particles of metal) or stereolithography (using lasers to cure liquid resin). A Brief History of 3D Printing Types of 3D Printers When you talk about 3D printing, you may mean one of the following: 3D printer A device that uses a digital blueprint to create a physical object by printing layer upon layer of material. This material can be plastic, metal or even living cells. There are different types of 3D printers, each with its own advantages and disadvantages. Some can print larger objects than others and some can print in more than one color. FDM (fused deposition modeling) One type of 3D printer that uses a filament spool to extrude plastic material, layer by layer, in order to create an object. FDM is the most common type of 3D printing technology and it's used by several different manufacturers like MakerBot and Stratasys. SLA (stereolithography) Another type of 3D printing technology that uses light shining through a liquid resin to harden it into an object as it's being printed layer by layer. The SLA process is slower than FDM but it produces higher quality parts due to the fact that there are fewer layers involved in the process and that each layer gets cured before adding another layer on top of it . The biggest drawback to the SLA process is that the resin used in it can be expensive and the finished parts are usually more delicate than those produced by FDM. Open Source vs. Closed Source The 3D printing industry is a lot like the Wild West. There are so many different types of printers and materials that it can be difficult to know which one is right for you. To help, we've created a brief guide to some of the most common terms you'll encounter when shopping for 3D printers. The biggest difference between open source 3D printers and closed source ones is that open source ones can be modified and improved by anyone who wants to do so because they use standard parts instead of proprietary ones. A closed source printer would have code that prevents users from being able to modify it in any way, shape or form without breaking copyright laws or licenses if they wanted to use their own parts instead of official ones sold by the manufacturer. The open-source movement has become increasingly popular in recent years, but it's not just software

that benefits from being open source — 3D printing does as well! Open-source printers are made by companies that release their designs and software codes for free, making them available for anyone to download and use at no cost. This allows for faster innovation within the industry, as well as more affordable prices for consumers who want to buy their own printer without having to spend thousands of dollars on proprietary parts or software licenses. Most of our printers fall into this category! Closed-source printers may be less expensive initially, but they're also less customizable and often require costly upgrades if you want to do anything beyond basic printing jobs. There are many reasons why companies choose to use closed source software, but all of them boil down to one thing: money. When you buy a piece of software, it's yours forever — or at least as long as you continue to pay for updates and support. The company that created it has no claim on your product, so if you're unhappy with it in any way, you can just walk away and find something else that works better for you. The same goes for hardware — if someone makes a 3D printer that doesn't work properly for some reason (or worse), then there's nothing stopping you from buying another one from someone else who does their job better than the first one did theirs. Speed of the Print Process The speed of the print process depends on several factors. One of them is the size of the object, which determines how much material needs to be deposited. If you are printing a large object, it will take longer than a small one. Another factor is the level of detail that you want to achieve in your print. The higher the detail, the slower the process becomes because more time is required for each layer to dry and become solid enough for printing to continue on top of it. The speed also depends on your printer manufacturer and model. Some printers have a lower maximum resolution than others, so they cannot achieve high-resolution prints at all speeds or at all layers; some have better hardware than others, allowing them to perform better overall; some have faster print heads (the part that deposits material), etc.. Cost of 3D Printing 3D printers are still a relatively new technology, so it's hard to know what the future will hold for them. However, there are some things we can say about their present. The cost of 3D printing is a big consideration for anyone looking to invest in one. The price of the printer itself can vary greatly depending on what you're looking for and where you buy it from. 3D printers can run from as little as $500 up to $10000 or more. The quality of the print also affects pricing. Some printers are able to produce higher quality prints than others, but this also comes with a higher price tag. 3D printing is a relatively new technology, and it's still evolving. There are many different types of printers available, with different price points and capabilities. There are two main types of 3D printers: FDM (Fused Deposition Modeling) and SLA (Stereolithography). FDM printers use plastic filaments that are melted and extruded through a nozzle to create layers of material one on top of another. SLA printers use a UV laser to solidify a liquid resin that is applied one layer at a time. If you want to get started with 3D printing right away, it's best to look at budget options first before investing in more expensive machines with more advanced features and capabilities that may not be necessary at this point. Each type has its own benefits and drawbacks: FDM - Cheap and easy to use, but low resolution models can take longer to print than those produced by other methods. SLA - High-quality prints in a short amount of time, but expensive materials cost more per print than FDM models. Where and How to Find Files to Print In order to print anything on your 3D printer, you need a file or template from an object that you want to print. There are several ways to get these files:

If you have access to an office or school computer with internet access and a printer driver installed, you can download files from sites like Thingiverse and MyMiniFactory. These sites have thousands of templates for objects that can be printed on most home 3D printers. If you don't have access to a computer with internet access but still want to print something from Thingiverse or MyMiniFactory, there are some smartphone apps that can help you find what you're looking for by using your camera's built-in scanner. These apps will scan any object that they see through their camera lens and then provide a list of matching options on their website or app store page where they found them . What's great about these mobile apps is that they allow the user more freedom than if they were simply using a computer, as they can scan objects that are not in front of a screen. The downside to these apps is that they require internet access in order to use them, which can be difficult if you don't have access or don't want to pay for data on your phone plan. Final 3D printing technology is going to change the world – so much so that it recently posed a threat to Obama's reelection campaign. It is a revolutionary, evolutionary step forward in technology which guarantees to have a huge impact on our lives. Yet the majority of us still do not know exactly what 3D printing actually is and how we can use it.

Over the years, I’ve learned a fair amount about maintaining (or coddling) a few different models of 3D printers: Makerbot (Cupcake, 2, 2x, 5th Gen), Printrbot (Simple Metal), Bits from Bytes (3D Touch and Cube), and Ultimaker (2+, Go, and Original+). Like the book about maintaining motorcycles, you can either buy a top of the line printer with awesome customer support and expect it to work amazingly, or you can get to know one intimately because you built it from a kit or from scratch and/or you found yourself elbow deep in a machine trying to troubleshoot with the help of Google, user forums, willpower, and luck. Desktop 3D printers are not “plug and play” — I have almost never been able to simply turn on and use a 3D printer without any frustrations.

I’ve spent the past two weeks in close proximity with two Ultimaker Original+ kit printers (built by Brearley students a few years ago). For better or worse, I removed and rebuilt the feeder assembly on both printers, and I’m still not satisfied with the feeder on the one sitting on my desk right now. I feel like I need to either remodel the students’ designs, change the Ultimaker’s settings, buy newer filament, and/or only print one thing at a time, as having the extruder “retract” during the print is causing problems with an already problematic feeder. I think I’ve narrowed it down to possibly needing a new ball bearing on the feeder clamp. When I notice filament isn’t advancing properly, I manually apply force to guide it from the spool to the opening of the feeder. It’s beyond tedious, and I’m sure the fumes (even from PLA) are making me stoopider.

I’ve taken to making tick marks on the filament with a permanent marker and anxiously staring to see if the filament advances properly. Essentially, I’ve learnt that the trick is to continually glare at it. As soon as I convince myself it’s working and walk away to attend to something else (or gloat), it fails. Every. Single. Time. I’m officially naming this one Christine.

But, oh, the satisfaction when it works…

(​I wrote a similarly titled post about 3D printer nerd-ery in 2013 here: https://karenblumberg.wordpress.com/2013/01/17/zen3dtouch/)

  Zen and the art of 3D printer maintenance redux. @BrearleyNYC #MakerEd #STEAM Over the years, I've learned a fair amount about maintaining (or coddling) a few different models of 3D printers: 

MakerBot - The proof is in the print. With more industrial features packed in per cubic inch, METHOD X #3Dprinter is truly in a class of its own. Print ABS with impossible dimensional accuracy. Print stiff and lightweight Nylon Carbon Fiber with ease. Need metal? It can do that too - print real 316L Stainless Steel and complete your project. 

Get to know the features that allow METHOD X to produce dimensionally accurate prototypes, industrial-strength tools, and production-grade parts. https://bit.ly/3BEydMC

PLUS: For a limited time get a FREE LABS Gen 2 Experimental Extruder when you purchase any METHOD 3D printer. Offer ends 8/13/2021.

I think people get confused when I say "accessible" in terms of price when it comes to specialized machinery. I don't mean "cheap" or even necessarily "affordable by the majority of people". I just mean "feasible to purchase as an individual as opposed to as an investment in capital for a business".

For a long time, computer based cutting machines, 3D printers, lazer cutters, sublimation printers, etc were all essentially manufacturing equipment not really available to the individual consumer. Now we're seeing more "home" versions of these machines within the price ranges of people intending to use them for personal use.

A 400 dollar sublimation printer is by no means "affordable", but the existing industrial counterpart which was the only option for a long time is often closer to 2 or 3 thousand. 400 is feasibly within the price range of an individual not using it for a business.

And, as these things become available to individual consumers, we see refinements of the consumer versions of them and competition in the market, which drives prices down. We're already seeing a lot of competition popping up to Cricut and loosening their chokehold on the cutting machine and htv vinyl markets as those become more and more popular with home crafters. Same with companies like Makerbot and 3D printing.

"Accessible" in this sense doesn't mean "affordable by the average Joe" so much as "feasibly obtainable by something other than a business", which is the first step to becoming the former.

The Makerbot Replicator+ is still the easiest 3D printer on the market

3D printing is in a bit of a doldrums. The novelty has worn off and the limited utility of the technology has been made clear. The bloom is especially off the rose of home 3D printing thanks to slow improvements in the actual technology involved in squirting plastic into clever shapes. There are only so many Yoda heads you can print before the 3D printer starts collecting dust. But it must be… Read More

https://techcrunch.com/2016/10/26/the-makerbot-replicator-is-still-the-easiest-3d-printer-on-the-market/?ncid=rss

Build Your Very on Robot! French artist Gael Langevin has whipped up a DIY robot design and achieve the plans online for anyone (including you) to download and adapt ... source

Researchers discover a new way to identify 3D printed guns

Researchers discover a new way to identify 3D printed guns

Researchers at the University at Buffalo have found that 3D printers have fingerprints, essentially slight differences in design that can be used to identify prints. This means investigators can examine the layers of a 3D printed object and pinpoint exactly which machine produced the parts.

“3D printing has many wonderful uses, but it’s also a counterfeiter’s dream. Even more concerning, it has…

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#5yrsago Tinkerers take over at White House Maker Faire

DIY enthusiasts gathered at the White House today at President Obama's invitation,  showing off their work at the first-ever White House Maker Faire.

The president said he hopes to “inspire a new wave of innovation”   generating new jobs and new industries to help rebuild America's economy.

More than 100 makers from 25 states were confirmed to attend, including "extreme marshmallow cannon" maker Jody Hudy, Super-Awesome Sylvia, who participated in Boing Boing's own Ford-sponsored automobile Hack Day.

Among the many Boing Boing friends participating,  Tara Brown, of the family-friendly LA Makerspace, and our friends at Makerbot, who produced the 3D representation of the White House below.

3D printing firm MakerBot participated in the #NationofMakers and  Day of Making in conjunction with the White House Maker Faire.  This 3D printed model of the White House was created and 3D printed by the MakerBot Studio in-house design team.

Today's event is part of the Obama administration's science, technology, engineering and math (STEM) programs.

https://boingboing.net/2014/06/18/tinkerers-take-over-at-white-h.html