![Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs43939-020-00004-6/MediaObjects/43939_2020_4_Fig1_HTML.png)
Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink
![Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs43939-020-00004-6/MediaObjects/43939_2020_4_Fig4_HTML.jpg)
Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink
![Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library](https://onlinelibrary.wiley.com/cms/asset/51505abf-f583-47d1-9d05-456b4bf79e5b/mame201900263-fig-0004-m.jpg)
Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library
![J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML](https://www.mdpi.com/jcs/jcs-06-00016/article_deploy/html/images/jcs-06-00016-g009.png)
J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML
![Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library](https://onlinelibrary.wiley.com/cms/asset/34b069a5-d0d1-4f87-a3ab-a89b71014122/mame201900263-fig-0005-m.jpg)
Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library
![J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML](https://www.mdpi.com/jcs/jcs-06-00016/article_deploy/html/images/jcs-06-00016-g003.png)
J. Compos. Sci. | Free Full-Text | 3D Printing under High Ambient Pressures and Improvement of Mechanical Properties of Printed Parts | HTML
![Robotics | Free Full-Text | Design and FDM/FFF Implementation of a Compact Omnidirectional Wheel for a Mobile Robot and Assessment of ABS and PLA Printing Materials | HTML Robotics | Free Full-Text | Design and FDM/FFF Implementation of a Compact Omnidirectional Wheel for a Mobile Robot and Assessment of ABS and PLA Printing Materials | HTML](https://www.mdpi.com/robotics/robotics-09-00043/article_deploy/html/images/robotics-09-00043-g001.png)
Robotics | Free Full-Text | Design and FDM/FFF Implementation of a Compact Omnidirectional Wheel for a Mobile Robot and Assessment of ABS and PLA Printing Materials | HTML
![Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library](https://onlinelibrary.wiley.com/cms/asset/fb4da090-eb58-4c07-8cef-dd2018dede6c/mame201900263-fig-0001-m.jpg)
Impact Optimization of 3D‐Printed Poly(methyl methacrylate) for Cranial Implants - Petersmann - 2019 - Macromolecular Materials and Engineering - Wiley Online Library
![Polymers | Free Full-Text | Mathematical Modeling and Optimization of Fused Filament Fabrication (FFF) Process Parameters for Shape Deviation Control of Polyamide 6 Using Taguchi Method | HTML Polymers | Free Full-Text | Mathematical Modeling and Optimization of Fused Filament Fabrication (FFF) Process Parameters for Shape Deviation Control of Polyamide 6 Using Taguchi Method | HTML](https://www.mdpi.com/polymers/polymers-13-03697/article_deploy/html/images/polymers-13-03697-g001.png)
Polymers | Free Full-Text | Mathematical Modeling and Optimization of Fused Filament Fabrication (FFF) Process Parameters for Shape Deviation Control of Polyamide 6 Using Taguchi Method | HTML
![Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs43939-020-00004-6/MediaObjects/43939_2020_4_Fig2_HTML.jpg)
Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink
![Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs43939-020-00004-6/MediaObjects/43939_2020_4_Fig5_HTML.png)
Using 3D printing to fabricate realistic test projectiles for natural fragmentation from buried charges | SpringerLink
![PodoPrinter launches insole application-specific 3D printer based on Blackbelt 3D technology - TCT Magazine PodoPrinter launches insole application-specific 3D printer based on Blackbelt 3D technology - TCT Magazine](https://www.tctmagazine.com/downloads/15783/download/PodoPrinter%20Sole%202.png?cb=f1416816b3e2f55ac894de639f0c2c42)