This document summarizes several additive manufacturing technologies for polymers, including stereolithography, 3D printing, laser sintering, and fused deposition modeling. It describes the basic processes and provides examples of applications for each technology. Key points covered include the ability to use different polymer materials, ranging from resins for stereolithography to powders for laser sintering. Examples are given for applications in various industries such as medical, consumer products, and architecture. Low-cost desktop 3D printing options are also reviewed. The conclusion covers the growing variety of additive manufacturing technologies and materials available for 3D printing polymers.
The document discusses electronic and technical textiles, specifically smart-functional textiles and their relevance for the construction industry. It provides an overview of Saxion University, including its research centers, chairs, and applied research in areas like healthcare, sustainability, and mobility. It also describes different types of technical textiles like buildtech for construction applications, and categories of smart-intelligent textiles, from conventional to passive to active electronic varieties. Enabling technologies for smart textiles like inkjet printing and nanotechnology are also mentioned.
This document summarizes a masterclass on the future of conductive printing held on November 27, 2012 in Belgium. It discusses two main printing technologies: inkjet printing and aerosol jet printing (AJP). For inkjet printing, it covers technology, printing requirements, results from the CLIP project testing silver and copper nanoparticle inks. For AJP, it describes the technology, compares it to other techniques, discusses conductive ink applications, and shows examples of 3D and flexible substrate printing done at Sirris with AJP. The conclusions state that AJP is well-suited for direct printing on 3D substrates and a wide range of ink viscosities, while inkjet can be scaled up for larger area printing.
The document discusses developments in conductive inks for printed electronics. It summarizes a masterclass on the future of conductive printing that covered: 1) the current status and types of conductive inks, 2) a EU project called CLIP that developed low-cost silver and copper nanoparticle inks for various printing methods, and 3) state-of-the-art developments by companies in producing more conductive and lower cost inks, such as NANOGAP's stable silver nanoparticle dispersions and multimodal particles. The conclusions are that while printed electronics growth has not met expectations, technical issues are now being solved and commercial uptake is increasing, which will help reduce costs and allow printed electronics to compete.
The document announces the official opening of the SLC-Lab on April 26, 2012. The day's program includes several presentations on composite materials and technologies, as well as a guided tour and networking event. The lab was created as a collaboration between universities and industry partners to enable composite product development from concept to production. It aims to support innovation by providing infrastructure for testing and prototyping without large investments.
NanoMarkets hosted a webinar on January 5th, 2012 about the market for silver inks and pastes from 2012-2019. They predicted a decline in the global market due to high silver prices and problems in the photovoltaic sector, though some growth was expected in sensors and flexible electronics. Alternatives to silver such as copper and aluminum may gain market share. Opportunities exist in developing products that reduce costs and enable miniaturization.
The document discusses conductive printing and sintering technologies. It provides an overview of IML, an expert in conductive inks and sintering. It then covers various factors to consider for conductive printing applications, different sintering options like broadband flash and lasers, new developments at IML, and examples of IML's work. IML aims to support R&D with affordable laser sintering tools and continue developing solutions to increase adoption of low-cost conductive inks.
The document discusses electronic and technical textiles, specifically smart-functional textiles and their relevance for the construction industry. It provides an overview of Saxion University, including its research centers, chairs, and applied research in areas like healthcare, sustainability, and mobility. It also describes different types of technical textiles like buildtech for construction applications, and categories of smart-intelligent textiles, from conventional to passive to active electronic varieties. Enabling technologies for smart textiles like inkjet printing and nanotechnology are also mentioned.
This document summarizes a masterclass on the future of conductive printing held on November 27, 2012 in Belgium. It discusses two main printing technologies: inkjet printing and aerosol jet printing (AJP). For inkjet printing, it covers technology, printing requirements, results from the CLIP project testing silver and copper nanoparticle inks. For AJP, it describes the technology, compares it to other techniques, discusses conductive ink applications, and shows examples of 3D and flexible substrate printing done at Sirris with AJP. The conclusions state that AJP is well-suited for direct printing on 3D substrates and a wide range of ink viscosities, while inkjet can be scaled up for larger area printing.
The document discusses developments in conductive inks for printed electronics. It summarizes a masterclass on the future of conductive printing that covered: 1) the current status and types of conductive inks, 2) a EU project called CLIP that developed low-cost silver and copper nanoparticle inks for various printing methods, and 3) state-of-the-art developments by companies in producing more conductive and lower cost inks, such as NANOGAP's stable silver nanoparticle dispersions and multimodal particles. The conclusions are that while printed electronics growth has not met expectations, technical issues are now being solved and commercial uptake is increasing, which will help reduce costs and allow printed electronics to compete.
The document announces the official opening of the SLC-Lab on April 26, 2012. The day's program includes several presentations on composite materials and technologies, as well as a guided tour and networking event. The lab was created as a collaboration between universities and industry partners to enable composite product development from concept to production. It aims to support innovation by providing infrastructure for testing and prototyping without large investments.
NanoMarkets hosted a webinar on January 5th, 2012 about the market for silver inks and pastes from 2012-2019. They predicted a decline in the global market due to high silver prices and problems in the photovoltaic sector, though some growth was expected in sensors and flexible electronics. Alternatives to silver such as copper and aluminum may gain market share. Opportunities exist in developing products that reduce costs and enable miniaturization.
The document discusses conductive printing and sintering technologies. It provides an overview of IML, an expert in conductive inks and sintering. It then covers various factors to consider for conductive printing applications, different sintering options like broadband flash and lasers, new developments at IML, and examples of IML's work. IML aims to support R&D with affordable laser sintering tools and continue developing solutions to increase adoption of low-cost conductive inks.
The document discusses additive manufacturing for ceramic parts. It describes how ceramics have properties like hardness, heat resistance, and corrosion resistance that make them useful for medical and industrial applications. Traditional ceramic manufacturing has limitations for custom or complex parts. Additive manufacturing allows for fast, low-cost production of complex ceramic parts in small volumes. The document outlines the key steps in additive manufacturing of ceramics: using ceramic powder, creating a paste, additive manufacturing, debinding, sintering, and optional post-treatment. Challenges include developing strong, dense materials and preventing cracking during sintering.
Sirris materials day 2011 small is smart - denis vandormael - sirrisSirris
The document discusses Sirris' SMALL (Smart Miniaturization Application Lab) facility. SMALL focuses on miniaturizing products and adding smart capabilities through microfabrication techniques like micro-machining, replication, surface functionalization, and printed electronics. These techniques allow for embedding sensors and creating multifunctional, customized solutions. Examples highlighted include a smart micro-needle patch, microfluidic devices, and printed electronics applications.
Sirris is a collective center for the Belgian technology industry located in Belgium. It has extensive additive manufacturing capabilities and competencies, including 15 engineers and technicians and machines in Liège and Charleroi. Some of its key additive manufacturing technologies are stereolithography, laser sintering of metals, electron beam melting, and its own Optoform process for producing custom implants and prosthetics in ceramics and metals for the medical industry. Sirris has applied these technologies to produce porous bone scaffolds and over 10,000 spinal implants.
The Sirris Microfabrication AppLication Lab (SMALL) at Sirris is active in the field of micro deposition and printed electronics by Aerosol Jet Printing technology (AJP). This new technology is very interesting in terms of material deposition on many types of substrates.
In order to gather ideas supported by industrial companies and to help industry innovate, Sirris and its SMALL laboratory equipped with AJP technology, invited people from industry to this workshop at the Sirris’ 'µPrinting Day'.
During this event, experts in Aerosol Jet printing technologies from OPTOMEC, a recognized leader in the field of additive manufacturing, were present.
The document discusses additive manufacturing techniques for high value manufacturing. It provides examples of how additive manufacturing allows for lightweighting of parts through complex internal geometries, multi-functional design, and topology optimization. Additive manufacturing enables customization, reduced assembly requirements, and optimization of part performance through features like conformal cooling channels and porous structures. The techniques allow innovative designs across industries like aerospace, medical, and consumer products.
Intellectual property, traceability and the counterfeiting of 3D printable objects
3D printing : legal issues and challenges
Fabienne Monfort-Windels - Sirris
EMS-GRILTECH manufactures and sells technical fibers, bonding agents, hot melt adhesives, crosslinkers, and reactive diluents. Their products are used in applications such as paper machine clothing, automotive, packaging, clothing, powder coatings, and civil engineering. EMS-GRILTECH has production facilities in Switzerland, Germany, and the US and sells their products worldwide through sales offices and agents. They focus on developing new products and applications to create value for customers.
Additive manufacturing (AM) offers a few major benefits to biomedical applications. To improve the knowledge on AM possibilities, Sirris is organizing two different masterclasses. The first will address the technology, materials used and applications, with experts in the matter explaining all relevant aspects.
The document discusses various applications of 3D printing including architecture, marketing, medicine, furniture, fashion, animation, and small-medium enterprises. It then details the 3D printing capabilities at IIPSI including fused deposition modeling (FDM), multi-jet modeling (MJM), laser sintering, and electron beam melting. Research activities exploring metallic and composite 3D printing, high resolution hybrid deposition, medical modeling, and low cost 3D printing are also summarized.
Piezoelectric Devices: From Bulk to Thin-Film 2019 report by Yole DéveloppementYole Developpement
How strongly will piezoelectric’s good vibrations resonate in the device market?
More information on https://www.i-micronews.com/products/piezoelectric-devices-from-bulk-to-thin-film-2019/
Ultra mICRO and mICRO Drills manufacturer in IndiaVIT1354
AXIS has extensive experience, technological expertiseto craft wide range of High Precision Micro-Tools with unique geometries ,designs and close tolerances to machine emerging / challenging job materials and which demand extremely close tolerances
AXIS NexGen Micro Drills encompasse application specific Drill designs, Ultra fine Tungsten. Ultra mICRO and mICRO Drills manufacturer in India
UV Nanoimprint Lithography Roll to Roll in 300 mm working width, available now at Coatema Coating Machinery GmbH in Dormagen, Germany. Unit is ready for use in the Coatema R&D centre.
The document discusses additive manufacturing (AM) techniques for thermoplastics. It describes fused deposition modeling (FDM) as the most commonly used AM process, where a plastic filament is heated and extruded through a nozzle to build 3D objects layer by layer. Common thermoplastics used in FDM include ABS, PLA, and nylon. The document outlines applications of FDM like rapid prototyping, manufacturing tools, and customized medical and consumer products. It concludes by discussing the company's vision to support 3D printing innovation in India through testing and collaboration with research organizations.
The document discusses additive manufacturing (AM) techniques for thermoplastics. It describes fused deposition modeling (FDM) as the most commonly used AM process, where a plastic filament is extruded through a heated nozzle to build 3D objects layer by layer. Common thermoplastics used in FDM include ABS, PLA, and nylon. The document outlines applications of FDM such as rapid prototyping, manufacturing tools, small series production, and customized medical devices. It concludes by outlining the company's vision to support 3D printing innovation in India through testing and collaboration with research organizations.
In Industry 4.0 or IoT the idea is that all machines will be connected and share data. This presentation shows some ideas how this could be translated to a machining environment. Also some breakthrough achievements, like tool wear measurment during cutting, are discussed.
3D printing is a method of additive manufacturing that builds up a solid object layer by layer from a digital file. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that each use different materials and processes to build objects layer by layer. 3D printing has applications across many industries like medical, mechanical, architecture, fashion, and jewelry for prototyping, production, and customized parts.
3D printing is a method of additive manufacturing that builds 3D objects layer by layer by adding material. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that use different materials and processes. 3D printing has applications across many industries like medical, mechanical, architecture, fashion, and jewelry for prototyping, production, and customized parts.
3D printing is a method of additive manufacturing that builds up a solid object layer by layer from a digital file. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that each use different techniques like lasers, liquid resins, or deposition of melted materials to build the layers. 3D printing has applications in industries like medicine, engineering, architecture, fashion, and jewelry for producing prototypes, models, and final products.
This document discusses training a machine learning model for embedded inference. It covers choosing a framework (TensorFlow Lite), hardware (Raspberry Pi PICO), and model (MobileNetV2). It then discusses training the model on a custom image dataset, compressing the model using quantization and pruning techniques, and evaluating the compressed model's accuracy and size. The goal is to optimize the model for fast and efficient inference on resource-constrained embedded hardware.
The document discusses Pattyn Group's data collection and analysis solutions for product quality control and equipment performance optimization. It describes Pattyn 360, which includes on-premise and cloud-based options for collecting machine data, storing it locally or in the cloud, and providing data export, dashboards, and analysis. The solutions help customers control production processes, improve product quality, and maximize equipment availability through remote support, predictive maintenance, and using historical data for continuous improvement. Pattyn aims to provide the right information at the right time to customers through an online portal and is running pilot projects to develop their solutions and business model further.
The document discusses additive manufacturing for ceramic parts. It describes how ceramics have properties like hardness, heat resistance, and corrosion resistance that make them useful for medical and industrial applications. Traditional ceramic manufacturing has limitations for custom or complex parts. Additive manufacturing allows for fast, low-cost production of complex ceramic parts in small volumes. The document outlines the key steps in additive manufacturing of ceramics: using ceramic powder, creating a paste, additive manufacturing, debinding, sintering, and optional post-treatment. Challenges include developing strong, dense materials and preventing cracking during sintering.
Sirris materials day 2011 small is smart - denis vandormael - sirrisSirris
The document discusses Sirris' SMALL (Smart Miniaturization Application Lab) facility. SMALL focuses on miniaturizing products and adding smart capabilities through microfabrication techniques like micro-machining, replication, surface functionalization, and printed electronics. These techniques allow for embedding sensors and creating multifunctional, customized solutions. Examples highlighted include a smart micro-needle patch, microfluidic devices, and printed electronics applications.
Sirris is a collective center for the Belgian technology industry located in Belgium. It has extensive additive manufacturing capabilities and competencies, including 15 engineers and technicians and machines in Liège and Charleroi. Some of its key additive manufacturing technologies are stereolithography, laser sintering of metals, electron beam melting, and its own Optoform process for producing custom implants and prosthetics in ceramics and metals for the medical industry. Sirris has applied these technologies to produce porous bone scaffolds and over 10,000 spinal implants.
The Sirris Microfabrication AppLication Lab (SMALL) at Sirris is active in the field of micro deposition and printed electronics by Aerosol Jet Printing technology (AJP). This new technology is very interesting in terms of material deposition on many types of substrates.
In order to gather ideas supported by industrial companies and to help industry innovate, Sirris and its SMALL laboratory equipped with AJP technology, invited people from industry to this workshop at the Sirris’ 'µPrinting Day'.
During this event, experts in Aerosol Jet printing technologies from OPTOMEC, a recognized leader in the field of additive manufacturing, were present.
The document discusses additive manufacturing techniques for high value manufacturing. It provides examples of how additive manufacturing allows for lightweighting of parts through complex internal geometries, multi-functional design, and topology optimization. Additive manufacturing enables customization, reduced assembly requirements, and optimization of part performance through features like conformal cooling channels and porous structures. The techniques allow innovative designs across industries like aerospace, medical, and consumer products.
Intellectual property, traceability and the counterfeiting of 3D printable objects
3D printing : legal issues and challenges
Fabienne Monfort-Windels - Sirris
EMS-GRILTECH manufactures and sells technical fibers, bonding agents, hot melt adhesives, crosslinkers, and reactive diluents. Their products are used in applications such as paper machine clothing, automotive, packaging, clothing, powder coatings, and civil engineering. EMS-GRILTECH has production facilities in Switzerland, Germany, and the US and sells their products worldwide through sales offices and agents. They focus on developing new products and applications to create value for customers.
Additive manufacturing (AM) offers a few major benefits to biomedical applications. To improve the knowledge on AM possibilities, Sirris is organizing two different masterclasses. The first will address the technology, materials used and applications, with experts in the matter explaining all relevant aspects.
The document discusses various applications of 3D printing including architecture, marketing, medicine, furniture, fashion, animation, and small-medium enterprises. It then details the 3D printing capabilities at IIPSI including fused deposition modeling (FDM), multi-jet modeling (MJM), laser sintering, and electron beam melting. Research activities exploring metallic and composite 3D printing, high resolution hybrid deposition, medical modeling, and low cost 3D printing are also summarized.
Piezoelectric Devices: From Bulk to Thin-Film 2019 report by Yole DéveloppementYole Developpement
How strongly will piezoelectric’s good vibrations resonate in the device market?
More information on https://www.i-micronews.com/products/piezoelectric-devices-from-bulk-to-thin-film-2019/
Ultra mICRO and mICRO Drills manufacturer in IndiaVIT1354
AXIS has extensive experience, technological expertiseto craft wide range of High Precision Micro-Tools with unique geometries ,designs and close tolerances to machine emerging / challenging job materials and which demand extremely close tolerances
AXIS NexGen Micro Drills encompasse application specific Drill designs, Ultra fine Tungsten. Ultra mICRO and mICRO Drills manufacturer in India
UV Nanoimprint Lithography Roll to Roll in 300 mm working width, available now at Coatema Coating Machinery GmbH in Dormagen, Germany. Unit is ready for use in the Coatema R&D centre.
The document discusses additive manufacturing (AM) techniques for thermoplastics. It describes fused deposition modeling (FDM) as the most commonly used AM process, where a plastic filament is heated and extruded through a nozzle to build 3D objects layer by layer. Common thermoplastics used in FDM include ABS, PLA, and nylon. The document outlines applications of FDM like rapid prototyping, manufacturing tools, and customized medical and consumer products. It concludes by discussing the company's vision to support 3D printing innovation in India through testing and collaboration with research organizations.
The document discusses additive manufacturing (AM) techniques for thermoplastics. It describes fused deposition modeling (FDM) as the most commonly used AM process, where a plastic filament is extruded through a heated nozzle to build 3D objects layer by layer. Common thermoplastics used in FDM include ABS, PLA, and nylon. The document outlines applications of FDM such as rapid prototyping, manufacturing tools, small series production, and customized medical devices. It concludes by outlining the company's vision to support 3D printing innovation in India through testing and collaboration with research organizations.
In Industry 4.0 or IoT the idea is that all machines will be connected and share data. This presentation shows some ideas how this could be translated to a machining environment. Also some breakthrough achievements, like tool wear measurment during cutting, are discussed.
3D printing is a method of additive manufacturing that builds up a solid object layer by layer from a digital file. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that each use different materials and processes to build objects layer by layer. 3D printing has applications across many industries like medical, mechanical, architecture, fashion, and jewelry for prototyping, production, and customized parts.
3D printing is a method of additive manufacturing that builds 3D objects layer by layer by adding material. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that use different materials and processes. 3D printing has applications across many industries like medical, mechanical, architecture, fashion, and jewelry for prototyping, production, and customized parts.
3D printing is a method of additive manufacturing that builds up a solid object layer by layer from a digital file. It allows for tangible goods to be produced from a digital design. There are several methods of 3D printing including selective laser sintering (SLS), stereolithography, fused deposition modeling (FDM), and polyjet matrix technology that each use different techniques like lasers, liquid resins, or deposition of melted materials to build the layers. 3D printing has applications in industries like medicine, engineering, architecture, fashion, and jewelry for producing prototypes, models, and final products.
Similar to 2012 11-08-3 d-printing-event-polymers (20)
This document discusses training a machine learning model for embedded inference. It covers choosing a framework (TensorFlow Lite), hardware (Raspberry Pi PICO), and model (MobileNetV2). It then discusses training the model on a custom image dataset, compressing the model using quantization and pruning techniques, and evaluating the compressed model's accuracy and size. The goal is to optimize the model for fast and efficient inference on resource-constrained embedded hardware.
The document discusses Pattyn Group's data collection and analysis solutions for product quality control and equipment performance optimization. It describes Pattyn 360, which includes on-premise and cloud-based options for collecting machine data, storing it locally or in the cloud, and providing data export, dashboards, and analysis. The solutions help customers control production processes, improve product quality, and maximize equipment availability through remote support, predictive maintenance, and using historical data for continuous improvement. Pattyn aims to provide the right information at the right time to customers through an online portal and is running pilot projects to develop their solutions and business model further.
2021 01-27 - webinar - Corrosie van 3D geprinte onderdelenSirris
Gebruikt u als bedrijf 3D-geprinte onderdelen of wilt u deze gebruiken? Dit webinar informeert u over de specifieke problematiek van corrosie die bij 3D-geprinte onderdelen kan optreden en licht de mogelijkheden tot deelname aan een onderzoeksproject hierrond toe.
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The document provides an overview of the additive manufacturing (AM) process for metal parts. It discusses selecting an AM technology and material, designing the part, setting up the job configuration, running the print, and performing quality checks. Key steps include choosing SLM, LMD, or WAAM based on the application; selecting a metal powder or wire material; optimizing the part design for the chosen technology; setting laser power and scan speed parameters to achieve the desired density and properties; and conducting inspections before and after any post-processing such as heat treatment.
Challenges and solutions for improved durability of materials - Opin summary ...Sirris
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Corrosion monitoring is important for the offshore renewable energy (ORE) sector due to the technical and economic consequences of corrosion. Current corrosion monitoring methods include corrosion coupons, ER probes, and environmental sensors for oxygen, pH, and temperature. However, these methods have limitations like needing retrieval, providing only historic data, and requiring frequent recalibration. New sensor technologies are needed for improved pitting monitoring, mudline corrosion inspection, and microbially influenced corrosion monitoring. Effective monitoring strategies combine direct corrosion monitoring with environmental data and inspections to reduce uncertainty and support corrosion risk-based inspection planning.
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1) The document discusses how value can be created through smart products using sensors, connectivity, and digital services.
2) It outlines common smart product design areas like business models, mechatronics, and digital services that can enable new competitive advantages.
3) The author argues that companies should apply validated inspiration from proven smart product scenarios, build expertise in proof of concepts, and scale up knowledge through an ecosystem network to successfully create value with smart products.
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