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==See | == See also == | ||
* https://patentcenter.uspto.gov/applications/90015140 | |||
==== RepRapable Recyclebot and the Wild West of Recycling ==== | |||
<div class="grid"> | |||
{{Video|b04mUaI-oTU}} | |||
===Recycling Technology=== | |||
{{Video|JxF5gunuM1A}} | |||
</div> | |||
=== Recycling Technology === | |||
* [[Recyclebot]] | * [[Recyclebot]] | ||
* [[RepRapable Recyclebot: Open source 3-D printable extruder for converting plastic to 3-D printing filament]] | |||
** [[Improving recyclebot concepts]] | * [[Open Source 3-D Filament Diameter Sensor for Recycling, Winding and Additive Manufacturing Machines]] | ||
* [[Improving recyclebot concepts]] | |||
* [[3-D Printable Polymer Pelletizer Chopper for Fused Granular Fabrication-Based Additive Manufacturing]] | * [[3-D Printable Polymer Pelletizer Chopper for Fused Granular Fabrication-Based Additive Manufacturing]] | ||
* [[Fused Particle Fabrication 3-D Printing: Recycled | * [[Mechanical Properties of Direct Waste Printing of Polylactic Acid with Universal Pellets Extruder: Comparison to Fused Filament Fabrication on Open-Source Desktop Three-Dimensional Printers]] | ||
* [[Fused Particle Fabrication 3-D Printing: Recycled Materials' Optimization and Mechanical Properties]] | |||
* [[Multi-material distributed recycling via material extrusion: recycled high density polyethylene and poly (ethylene terephthalate) mixture]] | |||
* [[Mechanical Properties and Applications of Recycled Polycarbonate Particle Material Extrusion-Based Additive Manufacturing]] | * [[Mechanical Properties and Applications of Recycled Polycarbonate Particle Material Extrusion-Based Additive Manufacturing]] | ||
* [[Wood Furniture Waste-Based Recycled 3-D Printing Filament]] | * [[Wood Furniture Waste-Based Recycled 3-D Printing Filament]] | ||
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* [[Mechanical Properties of Ultraviolet-Assisted Paste Extrusion and Postextrusion Ultraviolet-Curing of Three-Dimensional Printed Biocomposites]] | * [[Mechanical Properties of Ultraviolet-Assisted Paste Extrusion and Postextrusion Ultraviolet-Curing of Three-Dimensional Printed Biocomposites]] | ||
* [[Open Source Waste Plastic Granulator]] | * [[Open Source Waste Plastic Granulator]] | ||
* [[Open-Source Grinding Machine for Compression Screw Manufacturing]] | |||
===Distributed Recycling LCA=== | * [[Sustainability and Feasibility Assessment of Distributed E-Waste Recycling using Additive Manufacturing in a Bi-Continental Context]] | ||
* [[Finding Ideal Parameters for Recycled Material Fused Particle Fabrication-Based 3D Printing Using an Open Source Software Implementation of Particle Swarm Optimization]] | |||
* [[Waste Plastic Direct Extrusion Hangprinter]] | |||
* [[Hangprinter for Large Scale Additive Manufacturing using Fused Particle Fabrication with Recycled Plastic and Continuous Feeding]] | |||
* [[Open Source Cold and Hot Scientific Sheet Press for Investigating Polymer-Based Material Properties]] | |||
=== Distributed Recycling LCA === | |||
* [[Tightening the loop on the circular economy: Coupled distributed recycling and manufacturing with recyclebot and RepRap 3-D printing]] | * [[Tightening the loop on the circular economy: Coupled distributed recycling and manufacturing with recyclebot and RepRap 3-D printing]] | ||
* [[Technical pathways for distributed recycling of polymer composites for distributed manufacturing: Windshield wiper blades]] | |||
* [[Plastic recycling in additive manufacturing: A systematic literature review and opportunities for the circular economy]] | |||
* [[Energy Payback Time of a Solar Photovoltaic Powered Waste Plastic Recyclebot System]] | * [[Energy Payback Time of a Solar Photovoltaic Powered Waste Plastic Recyclebot System]] | ||
* [[Life cycle analysis of distributed recycling of post-consumer high density polyethylene for 3-D printing filament]] | * [[Life cycle analysis of distributed recycling of post-consumer high density polyethylene for 3-D printing filament]] | ||
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* [[Green Fab Lab Applications of Large-Area Waste Polymer-based Additive Manufacturing]] | * [[Green Fab Lab Applications of Large-Area Waste Polymer-based Additive Manufacturing]] | ||
* [[Systems Analysis for PET and Olefin Polymers in a Circular Economy]] | * [[Systems Analysis for PET and Olefin Polymers in a Circular Economy]] | ||
* [[Potential of distributed recycling from hybrid manufacturing of 3-D printing and injection molding of stamp sand and acrylonitrile styrene acrylate waste composite]] | |||
* [[Towards Distributed Recycling with Additive Manufacturing of PET Flake Feedstocks]] | |||
=== Literature Reviews === | |||
[[File:gigarecycle.png|thumb]] | |||
* [[Waste plastic extruder: literature review]] | |||
* [[Life cycle analysis of polymer recycling literature review]] | |||
* [[Solar powered recyclebot literature review]] | |||
* [[Waste plastic extruder: literature review]] | |||
* [[Life cycle analysis of polymer recycling literature review]] | |||
=== | === Externals === | ||
* [http://www.economist.com/news/science-and-technology/21565577-new-manufacturing-technique-could-help-poor-countries-well-rich-ones Economist article on U. of Washington's HDPE boat], [http://web.archive.org/web/20150420060330/http://open3dp.me.washington.edu/2012/07/woof-rocks-the-boat/ Oprn3dp.me] | |||
* [http://www.economist.com/news/science-and-technology/21565577-new-manufacturing-technique-could-help-poor-countries-well-rich-ones Economist article on U. of Washington's HDPE boat], [http://open3dp.me.washington.edu/2012/07/woof-rocks-the-boat/ Oprn3dp.me] | |||
* https://ultimaker.com/en/resources/52444-ocean-plastic-community-project | * https://ultimaker.com/en/resources/52444-ocean-plastic-community-project | ||
* Another possible solution - reusable containers [https://www.cnn.com/interactive/2019/01/business/loop-reusable-packaging-mission-ahead/index.html] | * Another possible solution - reusable containers [https://www.cnn.com/interactive/2019/01/business/loop-reusable-packaging-mission-ahead/index.html] | ||
---- | * Commercial https://dyzedesign.com/pulsar-pellet-extruder/ | ||
* Cruz, F., Lanza, S., Boudaoud, H., Hoppe, S., & Camargo, M. Polymer Recycling and Additive Manufacturing in an Open Source context: Optimization of processes and methods. [http://sffsymposium.engr.utexas.edu/sites/default/files/2015/2015-127-Cruz.pdf] | * --- | ||
* Investigating Material Degradation through the Recycling of PLA in Additively Manufactured Parts | * Cruz, F., Lanza, S., Boudaoud, H., Hoppe, S., & Camargo, M. Polymer Recycling and Additive Manufacturing in an Open Source context: Optimization of processes and methods. [http://web.archive.org/web/20190819114523/http://sffsymposium.engr.utexas.edu:80/sites/default/files/2015/2015-127-Cruz.pdf] | ||
* Mohammed, M.I., Das, A., Gomez-Kervin, E., Wilson, D. and Gibson, I., EcoPrinting: Investigating the use of 100% recycled Acrylonitrile Butadiene Styrene (ABS) for Additive Manufacturing. | * Investigating Material Degradation through the Recycling of PLA in Additively Manufactured Parts | ||
* Mohammed, M.I., Das, A., Gomez-Kervin, E., Wilson, D. and Gibson, I., EcoPrinting: Investigating the use of 100% recycled Acrylonitrile Butadiene Styrene (ABS) for Additive Manufacturing. | |||
* Kariz, M., Sernek, M., Obućina, M. and Kuzman, M.K., 2017. Effect of wood content in FDM filament on properties of 3D printed parts. Materials Today Communications. [https://www.sciencedirect.com/science/article/pii/S2352492817302635] | * Kariz, M., Sernek, M., Obućina, M. and Kuzman, M.K., 2017. Effect of wood content in FDM filament on properties of 3D printed parts. Materials Today Communications. [https://www.sciencedirect.com/science/article/pii/S2352492817302635] | ||
* Kaynak, B., Spoerk, M., Shirole, A., Ziegler, W. and Sapkota, J., 2018. Polypropylene/Cellulose Composites for Material Extrusion Additive Manufacturing. Macromolecular Materials and Engineering, p.1800037. [https://onlinelibrary.wiley.com/doi/pdf/10.1002/mame.201800037] | * Kaynak, B., Spoerk, M., Shirole, A., Ziegler, W. and Sapkota, J., 2018. Polypropylene/Cellulose Composites for Material Extrusion Additive Manufacturing. Macromolecular Materials and Engineering, p.1800037. [https://onlinelibrary.wiley.com/doi/pdf/10.1002/mame.201800037] | ||
* O. Martikka et al., "Mechanical Properties of 3D-Printed Wood-Plastic Composites", Key Engineering Materials, Vol. 777, pp. 499-507, 2018 [https://www.scientific.net/KEM.777.499] | * O. Martikka et al., "Mechanical Properties of 3D-Printed Wood-Plastic Composites", Key Engineering Materials, Vol. 777, pp. 499-507, 2018 [https://www.scientific.net/KEM.777.499] | ||
* Yang, T.C., 2018. Effect of Extrusion Temperature on the Physico-Mechanical Properties of Unidirectional Wood Fiber-Reinforced Polylactic Acid Composite (WFRPC) Components Using Fused Deposition Modeling. Polymers, 10(9), p.976. [http://www.mdpi.com/2073-4360/10/9/976] | * Yang, T.C., 2018. Effect of Extrusion Temperature on the Physico-Mechanical Properties of Unidirectional Wood Fiber-Reinforced Polylactic Acid Composite (WFRPC) Components Using Fused Deposition Modeling. Polymers, 10(9), p.976. [http://www.mdpi.com/2073-4360/10/9/976] | ||
* Romani, A., Rognoli, V., & Levi, M. (2021). Design, Materials, and Extrusion-Based Additive Manufacturing in Circular Economy Contexts: From Waste to New Products. Sustainability, 13(13), 7269. https://www.mdpi.com/2071-1050/13/13/7269/pdf | |||
[[Category:Polymer recycling]] | [[Category:Polymer recycling]] |
Latest revision as of 13:43, 16 August 2024
See also[edit source]
RepRapable Recyclebot and the Wild West of Recycling[edit source]
Recycling Technology[edit source]
- Recyclebot
- RepRapable Recyclebot: Open source 3-D printable extruder for converting plastic to 3-D printing filament
- Open Source 3-D Filament Diameter Sensor for Recycling, Winding and Additive Manufacturing Machines
- Improving recyclebot concepts
- 3-D Printable Polymer Pelletizer Chopper for Fused Granular Fabrication-Based Additive Manufacturing
- Mechanical Properties of Direct Waste Printing of Polylactic Acid with Universal Pellets Extruder: Comparison to Fused Filament Fabrication on Open-Source Desktop Three-Dimensional Printers
- Fused Particle Fabrication 3-D Printing: Recycled Materials' Optimization and Mechanical Properties
- Multi-material distributed recycling via material extrusion: recycled high density polyethylene and poly (ethylene terephthalate) mixture
- Mechanical Properties and Applications of Recycled Polycarbonate Particle Material Extrusion-Based Additive Manufacturing
- Wood Furniture Waste-Based Recycled 3-D Printing Filament
- Solar powered distributed customized manufacturing
- Mechanical Properties of Ultraviolet-Assisted Paste Extrusion and Postextrusion Ultraviolet-Curing of Three-Dimensional Printed Biocomposites
- Open Source Waste Plastic Granulator
- Open-Source Grinding Machine for Compression Screw Manufacturing
- Sustainability and Feasibility Assessment of Distributed E-Waste Recycling using Additive Manufacturing in a Bi-Continental Context
- Finding Ideal Parameters for Recycled Material Fused Particle Fabrication-Based 3D Printing Using an Open Source Software Implementation of Particle Swarm Optimization
- Waste Plastic Direct Extrusion Hangprinter
- Hangprinter for Large Scale Additive Manufacturing using Fused Particle Fabrication with Recycled Plastic and Continuous Feeding
- Open Source Cold and Hot Scientific Sheet Press for Investigating Polymer-Based Material Properties
Distributed Recycling LCA[edit source]
- Tightening the loop on the circular economy: Coupled distributed recycling and manufacturing with recyclebot and RepRap 3-D printing
- Technical pathways for distributed recycling of polymer composites for distributed manufacturing: Windshield wiper blades
- Plastic recycling in additive manufacturing: A systematic literature review and opportunities for the circular economy
- Energy Payback Time of a Solar Photovoltaic Powered Waste Plastic Recyclebot System
- Life cycle analysis of distributed recycling of post-consumer high density polyethylene for 3-D printing filament
- Evaluation of Potential Fair Trade Standards for an Ethical 3-D Printing Filament
- Life cycle analysis of distributed polymer recycling
- Distributed recycling of post-consumer plastic waste in rural areas
- Ethical Filament Foundation
- Green Fab Lab Applications of Large-Area Waste Polymer-based Additive Manufacturing
- Systems Analysis for PET and Olefin Polymers in a Circular Economy
- Potential of distributed recycling from hybrid manufacturing of 3-D printing and injection molding of stamp sand and acrylonitrile styrene acrylate waste composite
- Towards Distributed Recycling with Additive Manufacturing of PET Flake Feedstocks
Literature Reviews[edit source]
- Waste plastic extruder: literature review
- Life cycle analysis of polymer recycling literature review
- Solar powered recyclebot literature review
- Waste plastic extruder: literature review
- Life cycle analysis of polymer recycling literature review
Externals[edit source]
- Economist article on U. of Washington's HDPE boat, Oprn3dp.me
- https://ultimaker.com/en/resources/52444-ocean-plastic-community-project
- Another possible solution - reusable containers [1]
- Commercial https://dyzedesign.com/pulsar-pellet-extruder/
- ---
- Cruz, F., Lanza, S., Boudaoud, H., Hoppe, S., & Camargo, M. Polymer Recycling and Additive Manufacturing in an Open Source context: Optimization of processes and methods. [2]
- Investigating Material Degradation through the Recycling of PLA in Additively Manufactured Parts
- Mohammed, M.I., Das, A., Gomez-Kervin, E., Wilson, D. and Gibson, I., EcoPrinting: Investigating the use of 100% recycled Acrylonitrile Butadiene Styrene (ABS) for Additive Manufacturing.
- Kariz, M., Sernek, M., Obućina, M. and Kuzman, M.K., 2017. Effect of wood content in FDM filament on properties of 3D printed parts. Materials Today Communications. [3]
- Kaynak, B., Spoerk, M., Shirole, A., Ziegler, W. and Sapkota, J., 2018. Polypropylene/Cellulose Composites for Material Extrusion Additive Manufacturing. Macromolecular Materials and Engineering, p.1800037. [4]
- O. Martikka et al., "Mechanical Properties of 3D-Printed Wood-Plastic Composites", Key Engineering Materials, Vol. 777, pp. 499-507, 2018 [5]
- Yang, T.C., 2018. Effect of Extrusion Temperature on the Physico-Mechanical Properties of Unidirectional Wood Fiber-Reinforced Polylactic Acid Composite (WFRPC) Components Using Fused Deposition Modeling. Polymers, 10(9), p.976. [6]
- Romani, A., Rognoli, V., & Levi, M. (2021). Design, Materials, and Extrusion-Based Additive Manufacturing in Circular Economy Contexts: From Waste to New Products. Sustainability, 13(13), 7269. https://www.mdpi.com/2071-1050/13/13/7269/pdf