Continuous Composites’ Post

Have you ever wondered how a company can completely change its production process, achieve an unparalleled level of efficiency, and save time like never before? By integrating 3D printing into their business, Cell2 has unlocked a world of possibilities. Rapid product innovation, quick turnaround for customer solutions, and enhanced adaptability are just a few of the benefits they've experienced.💡 Thanks to the Raise3D Technologies Pro3 and ASA material, Cell2 doesn't just provide quick solutions – they redefine what's possible! From concept to creation, witness the seamless integration of technology that reduces production times and elevates efficiency. 👉Discover more about Raise3D: https://lnkd.in/euc62xni 👉Book a Consultation: https://lnkd.in/eAgWuJdR #cell2 #3dprintingrevolution #efficiency #futureofmanufacturing #enhancedadaptability

In the ever-evolving world of 3D printing, speed is crucial. Recent advancements in high-speed printing technologies, such as Continuous Liquid Interface Production (CLIP) and High-Speed Sintering (HSS), are drastically cutting down print times, making 3D printing more efficient and accessible than ever before. Continuous Liquid Interface Production (CLIP): CLIP is a groundbreaking technique that uses a continuous sequence of UV images projected through an oxygen-permeable window. This process cures the resin into a solid object, layer by layer, at rapid speeds. The result? High-resolution parts that are produced in a fraction of the time compared to traditional methods. High-Speed Sintering (HSS): HSS is another game-changing technology that utilizes infrared lamps to sinter powder materials layer by layer. This method significantly accelerates the printing process, enabling the rapid production of durable and functional parts. HSS is especially beneficial for producing larger batches of parts, making it ideal for industrial applications. #highspeedprinting #clip #hss #manufacturingrevolution #3dprinting #3dprintingindustry #3dprintingservice #additivemanufacturing #rapidprototyping #3dprototyping #3dcad #3dscanning #3dmodeling

🤷♂️ 🤷♀️ Are you still troubled by the fact that the traditional molding process cannot produce it after design? 📢 Today, I recommend the SLA 3D printing process to you, which can help you overcome processing problems, quickly produce prototypes, and shorten your time to market! This technology builds parts layer by layer from liquid resin materials. It has the advantages of fast molding speed, high precision, and high surface finish. It solves the problems of high cost, difficult processing, and low efficiency of many parts. SLA 3D Printing Market by Application 🔎 🔔 Aerospace and Defense 🔔 Tool and Mold Making 🔔 Automotive 🔔 Healthcare 🔔 Academic Institutions #3DPRINTING #3DPRINTINGSERVICE #SLA #LightCuring #PhotosensitiveResin #QuickPrototyping #AdditiveManufacturing

Estimated reading time: 2-3 minutes -------------------------------------------------- The primary challenge faced by products manufactured through additive methods, such as the metal 3D printing process (LPBF), is the presence of porosities or microcavities, which must be minimized to mitigate the risk of premature breakage. A key strategy in addressing this challenge involves optimizing the parameters of the printing process. These parameters include: - Scanning speed - Laser or electronic power - Powder bed uniformity - Hatching parameters - Thickness of the powder layer - Atmosphere of the build chamber By carefully selecting and adjusting these parameters, the quality of the printed parts can be significantly enhanced and improved, reducing the occurrence of defects such as porosities. Proper control of parameters like scanning speed is particularly crucial in achieving optimal results. #AdditiveManufacturing #3DPrinting #MetalPrinting #LPBF #ManufacturingTechnology #QualityControl #ProductOptimization #Engineering #Innovation #ProductDesign #MaterialsScience #ManufacturingProcesses #DigitalManufacturing #Industry40 #LinkedInNetworking

Exciting news from Formlabs. Let me know if you would like some additional information!

Explore the dynamic world of 3D printing, a promising solution in engineering and manufacturing. Sponsored by igus, our guide delves into wear-resistant plastics, covering their origin, benefits, and printing technologies. Valuable insights for engineers and industry professionals alike. Download the full guide: https://lnkd.in/eRsThkqc #3dprinting #additivemanufacturing #technology #plastics #engineering #prototyping #3d #manufacturing #materialscience #materialengineering

In the world of emerging technologies, there are terms that may be unfamiliar. We are here to help! The materials used for 3D printing are often anisotropic, meaning they're better able to resist force applied in one direction than another. Organizations using 3D printing for final products—particularly ones designed to support weight—must consider the orientation of printed parts and their directional weaknesses. Check out this video from Andrew Stockett as he explains how his 3D printed object broke thanks to anisotropic materials: https://buff.ly/3Lqi8jH Every other week, MIT Horizon will share easy-to-understand definitions of terms used in the #EmTech arena. If there’s a specific term you’d like to know more about, let us know in the comments below. #EmergingTechnology #TechnologyVocabulary #AM #AdditiveManufacturing

Using two colors of light in 3D printing has advanced the creation of multi-material objects in a single print. This dual-wavelength photoreactive system development has led to increased printing speeds, lower resolution thresholds, and the creation of multi-material objects. However, the pace of development varies based on how the two colors of light are employed. Four dual-wavelength reaction types have been reported: synergistic (λ1 AND λ2), antagonistic (reversed λ1 AND λ2), orthogonal (λ1 OR λ2), and cooperative (λ1 AND λ2 or λ1 OR λ2). These developments come with chemical challenges that must be overcome for multi-wavelength additive manufacturing technologies to progress beyond their current limitations. Read more details: https://lnkd.in/dvAzPjee #polymerscience #3dprinting

As parts get smaller, traditional manufacturing methods become more challenging to use. That’s where 3D printing technology PµSL (Micro SLA) steps in. Developed by BMF, this ultra-high-resolution machine has a build envelope of 100 x 100 x 75 mm. Parts are characterised by high accuracy, extremely fine detail and exceptionally smooth surfaces. Learn more on our website: https://buff.ly/3PMDudC #medtech #electronics #microsla #projectionmicrostereolithography #productdesign #designengineering #engineering #industrialdesign #lifesciences #medicaldevices #biotech #biotechnology #drugdelivery #drugdeliverydevices #electronictechnology #electronictech #opticaltech #optical #3dprinting

Ever wondered how 3D printing is reshaping industrial filtration? . . . Join us on July 11th for an eye-opening webinar into the world of Additive Manufacturing and its game-changing impact on the industry. Our guide? None other than Scott Hopkins, a true industry sage with over four decades of experience! What's in store: • A time travel through AM's evolution in filtration • A sneak peek into tomorrow's industrial filtration frontiers • Nuggets of wisdom from Scott's 40-year treasure trove But wait, there's more! You'll get to pick Scott's brain during the Q&A. Don't let this opportunity slip through the cracks (or should we say, filters? 😉) Secure your virtual seat now: https://lnkd.in/gjV268h6 See you there! #filtration #innovation #3DPrinting #manufacturing #additivemanufacturing