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Decarbonizing the construction industry takes a big step forward! Research from NTU Singapore shows a new 3D concrete printing method can lock in 38% more CO2 than existing options. This innovative approach uses steam and CO2 injection, improving concrete strength and flexibility while offering a greener alternative to traditional methods. #sustainability #construction #carbonreduction #greentechnology #concrete

Revolutionizing foundry processes! Laempe's new automated 3D sand core printing line offers high speed, flexibility (open material system), and scalability. This technology enables foundries to economically transition from traditional core shooting to additive manufacturing, creating new growth opportunities. #foundry #3Dprinting #additivemanufacturing #manufacturingtechnology

Researchers at Nanyang Technological University (NTU) in Singapore have developed a revolutionary 3D concrete printing technique that captures carbon, offering a significant step towards greener construction. This innovation addresses the environmental impact of cement, a major contributor to global CO2 emissions. Key Highlights: Carbon Capture: The process integrates CO2 and steam (industrial by-products) directly into the concrete mix, permanently fixing the CO2 within the concrete structure. Enhanced Performance: The resulting concrete is significantly stronger and more durable, supporting up to 37% more weight and bending 45% more before breaking compared to conventional 3D-printed concrete. Reduced Environmental Impact: Captures 38% more CO2 than traditional methods, offering a carbon-reducing alternative to traditional cement production. Optimized Process: The 3D printer is connected to CO2 pumps and a steam jet, maximizing CO2 absorption and solidification. This breakthrough has the potential to transform the construction industry by: Reducing reliance on traditional, carbon-intensive methods like reinforced concrete. Optimizing material use and speeding up construction times. Lowering labor requirements. This research, published in Carbon Capture Science & Technology, demonstrates the potential of using captured industrial CO2 for sustainable construction. Researchers aim to further refine the technique and explore the use of recycled industrial gases. #3DPrinting #Construction #Sustainability #Innovation #Concrete #CarbonCapture #GreenBuilding #NTU #Singapore #EcoFriendly

Graphene's exceptional properties are transforming energy storage through 3D printing. This innovative approach allows for the creation of custom-designed structures with enhanced performance in batteries, supercapacitors, and more. Key Advantages: Enhanced Performance: Graphene's conductivity and large surface area boost energy density, charge-discharge rates, and overall efficiency. Customization: 3D printing enables precise control over material placement, creating optimized porosity and functionality for specific applications. Versatile Applications: From renewable energy storage for solar and wind power to flexible batteries for wearable devices, the possibilities are vast. Sustainable Manufacturing: Minimizes material waste and reduces production costs compared to conventional methods. Techniques like FDM and SLA are used to create intricate graphene-based structures: FDM: Deposits graphene-embedded thermoplastic filaments layer by layer for durable components. SLA: Uses photopolymerization to create smooth and detailed structures with high precision. Applications in Energy Systems: Renewable Energy Storage Hybrid Energy Systems Lithium-Ion & Sodium-Ion Batteries Supercapacitors Flexible Energy Storage Devices The combination of graphene and 3D printing is paving the way for next-generation energy storage solutions. #graphene #3dprinting #energystorage #innovation #sustainability #batteries #supercapacitors #renewableenergy

Revolutionizing Tissue Engineering: A Leap Forward in Bioprinting Scientists at Penn State University have made a significant breakthrough in bioprinting technology! Their innovative HITS-Bio system can rapidly create complex tissues using cellular spheroids. This method is 10 times faster than traditional techniques and maintains high cell viability. This advancement paves the way for faster tissue engineering and opens new doors for regenerative medicine. #bioprinting #tissueengineering #regenerativemedicine #science #innovation #PennState

Revolutionizing 3D Printing with Voxel Interface Control 3D printing is taking a giant leap forward! Researchers at Johns Hopkins University have developed a new technique called Voxel Interface 3D Printing (VI3DP) that allows for precise control over the interfaces between individual voxels. This groundbreaking method empowers us to tailor the properties of 3D-printed objects, leading to enhanced strength, functionality, and a wide range of applications. From complex 3D circuits to electromechanical devices, the possibilities are endless! #3Dprinting #innovation #engineering #JohnsHopkins #VI3DP #materialscience

Revolutionizing Soft Plastics with 3D Printing Engineers at Princeton, led by Prof. Emily Davidson, have developed a scalable 3D printing technique for creating recyclable, cost-effective, and customizable soft plastics. Using thermoplastic elastomers, they’ve achieved materials with tunable flexibility and stiffness, perfect for applications like soft robotics, medical devices, and even high-performance shoe soles. Key innovations: Nanostructures for Tunable Properties: Orientation of nanoscale cylinders allows control over material stiffness and stretchiness. Affordable and Sustainable: Materials cost ~$0.01/gram and are recyclable and self-healing with thermal annealing. Versatile Applications: From glowing plastics to complex multi-layered designs. This breakthrough could redefine industries with soft, adaptable, and eco-friendly materials. #3DPrinting #Innovation #MaterialScience #Engineering

Industrial 3D Printing: A Bright Future Ahead? CONTEXT's latest report forecasts a rebound in industrial 3D printer shipments in 2025, driven by falling interest rates. While the market experienced a decline in the first half of 2024, especially in the higher-end segments, the outlook remains positive. Key Takeaways: Industrial Segment: A 15% increase in shipments is projected for 2025, bringing sales back to 2021 levels. Consumer Segment: Entry-level printers continue to soar, with a 41% increase in shipments. Mid-range and Professional Segments: While facing challenges, these segments are expected to recover in 2025. #3DPrinting #AdditiveManufacturing #IndustryTrends #Technology #Innovation

Elegoo's Saturn 4 Ultra Wins Fast Company's Next Big Things in Tech Award 2024! 🎉 Our best-selling 3D printer, known for its innovative Tilt Release Technology, has been recognized for its breakthrough speed and reliability. 🏆 #Elegoo #Saturn4Ultra #3Dprinting #innovation #FastCompany #NextBigThingsInTech

🌊 Large-scale, High-Precision 3D Printing: WASP's latest HDP printer, the POWER WASP 45 HDP, is revolutionizing the nautical industry. 1 🌊 Complex Geometries, Minimal Support: The printer's innovative kinematic system allows for the creation of intricate designs without the need for extensive support structures. 2 🌊 Sustainable and Efficient: By directly 3D printing molds and components, manufacturers can reduce material waste and production time. Learn more about how WASP is shaping the future of nautical manufacturing. #3DPrinting #AdditiveManufacturing #WASP #Nautical #Innovation #Technology #Engineering