Chapter 13. Dimensional analysis of 3D-printed knuckle joint and bearing pillow block
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Pawan Kumar Rakesh
Abstract
The knuckle joint and bearing pillow block were designed on SolidWorks software. The meshing has been done to discretize the object in an element. Knuckle joint is printed by PolyJet printing technology (Objet 30 Scholar by STRATASYS). Bearing Pillow Block is printed by fused deposition modeling technology (Ultimaker2 Extended+ by ULTIMAKER). Its dimensional testing was performed using co-ordinate measuring machine (by Zeiss). The experimental results obtained showed positive and negative deviation on the 3D-printed objects as compared to actual dimensions. It was concluded that flatness is better achieved for parts produced by PolyJet technology. It was also concluded that flatness shows sufficient deviation but roundness has low deviation.
Abstract
The knuckle joint and bearing pillow block were designed on SolidWorks software. The meshing has been done to discretize the object in an element. Knuckle joint is printed by PolyJet printing technology (Objet 30 Scholar by STRATASYS). Bearing Pillow Block is printed by fused deposition modeling technology (Ultimaker2 Extended+ by ULTIMAKER). Its dimensional testing was performed using co-ordinate measuring machine (by Zeiss). The experimental results obtained showed positive and negative deviation on the 3D-printed objects as compared to actual dimensions. It was concluded that flatness is better achieved for parts produced by PolyJet technology. It was also concluded that flatness shows sufficient deviation but roundness has low deviation.
Kapitel in diesem Buch
- Frontmatter I
- Contents V
- Contributing authors VII
- Chapter 1. Processing on polylactic acid and its applications 1
- Chapter 2. Polylactic acid-agave fiber biocomposites: processing, properties, weathering performance, and biodegradation 13
- Chapter 3. Polylactic acid composite materials for packaging and the consumption of food products 31
- Chapter 4. Antibacterial properties of polylactic acid composites for food packaging 73
- Chapter 5. Barrier properties of polylactic acid 101
- Chapter 6. Heat-sealing properties of polylactic acid and polylactic acid composites 123
- Chapter 7. Reactive extrusion of polylactic acid 141
- Chapter 8. Surface properties of polylactic acid–based composites 163
- Chapter 9. Study on mechanical properties of Himalayacalamus falconeri fiber-reinforced polylactic acid composites 181
- Chapter 10. The fabrication process of the pine needle fiber-reinforced polylactic acid composites 217
- Chapter 11. Development of novel hybrid green polymer composites (HGPC) with a combination of biowaste material as fillers 227
- Chapter 12. Joining behavior of bio-filler-based polyester composites 257
- Chapter 13. Dimensional analysis of 3D-printed knuckle joint and bearing pillow block 271
- Chapter 14. Processing and applications of silk fiber-reinforced biocomposite for tissue engineering 289
- Chapter 15. The development of silk fiber-, jute fiber-, Grewia optiva fiber-reinforced biopolymer composites 303
- Chapter 16. Machinability characteristics of pine needle fiber-reinforced polylactic acid composites 321
- Index 331
Kapitel in diesem Buch
- Frontmatter I
- Contents V
- Contributing authors VII
- Chapter 1. Processing on polylactic acid and its applications 1
- Chapter 2. Polylactic acid-agave fiber biocomposites: processing, properties, weathering performance, and biodegradation 13
- Chapter 3. Polylactic acid composite materials for packaging and the consumption of food products 31
- Chapter 4. Antibacterial properties of polylactic acid composites for food packaging 73
- Chapter 5. Barrier properties of polylactic acid 101
- Chapter 6. Heat-sealing properties of polylactic acid and polylactic acid composites 123
- Chapter 7. Reactive extrusion of polylactic acid 141
- Chapter 8. Surface properties of polylactic acid–based composites 163
- Chapter 9. Study on mechanical properties of Himalayacalamus falconeri fiber-reinforced polylactic acid composites 181
- Chapter 10. The fabrication process of the pine needle fiber-reinforced polylactic acid composites 217
- Chapter 11. Development of novel hybrid green polymer composites (HGPC) with a combination of biowaste material as fillers 227
- Chapter 12. Joining behavior of bio-filler-based polyester composites 257
- Chapter 13. Dimensional analysis of 3D-printed knuckle joint and bearing pillow block 271
- Chapter 14. Processing and applications of silk fiber-reinforced biocomposite for tissue engineering 289
- Chapter 15. The development of silk fiber-, jute fiber-, Grewia optiva fiber-reinforced biopolymer composites 303
- Chapter 16. Machinability characteristics of pine needle fiber-reinforced polylactic acid composites 321
- Index 331
