Abstract
İşbirlikçi (kollaboratif)
endüstriyel robotlar dijital endüstride yerini almaya başlayan temel
ihtiyaçlardan birini oluşturmaktadır. Robotik alanında elde edilen gelişmeler
doğrudan robot-insan etkileşimi konusunda ilerlemeye katkısı bulunmaktadır. Bu
çalışmada, dijital endüstride yaygınlaşan işbirlikçi robotlar ve esnek robotik
sistemlerin sistematik analizi yapılarak bu robotların temel gelişim konsepti
araştırılmıştır.
References
- [1] Yeni sanayi devrimi akıllı üretim sistemleri yol haritası, TÜBİTAK Bilim, Teknoloji ve Yenilik Politikaları Daire Başkanlığı (2016).
- [2] A. Amir, G. Sascha, S. Francesca, (2016) Metrics and benchmarks in human-robot interaction: Recent Advances in cognitive robotics, Cognitive Systems Research.
- [3] C. Andrea, P. Robin, C. Andre, L. Antoine, F. Philippe (2016) Collaborative manufacturing with physical human-robot interaction, Robotics and Computer-Integrated Manufacturing, 40 1-13.
- [4] J. Krüger, T. K. Lien, A. Verl, (2009) Cooperation of human and machines in assembly lines, Manufacturing Technology, (58) 628-646.
- [5] G. Michalosa, S. Makrisa, P. Tsarouchia, T.Guaschb, D. Kontovrakisa, G.Chryssolourisa (2015) Design considerations for safe human-robot collaborative workplaces, Procedia CIRP (37) 248 – 253.
- [6] P. Akella, M. Peshkin, E. Colgate, W. Wannasuphoprasit, N. Nagesh, J. Wells, S. Holland, T. Pearson, B. Peacock (1999) Cobots for the automobile assembly line, IEEE, ICRA.
- [7] G. Michalos, S. Makris, N. Papakostas, D. Mourtzis, G. Chryssolouris (2010) Automotive assembly Technologies review: challenges and outlook for a flexible and adaptive approach, Manufacturing Technology (2) 81–91.
- [8] N. Papakostas, G. Michalos, S. Makris, D. Zouzias, G. Chryssolouris (2011) Industrial applications with cooperating robots for the flexible assembly, Int.J.Comput. Integr.Manuf. 24 (7) 650–660.
- [9] H. Sahin, and H. Guvenc (2007) Household robotics: Autonomous devices for vacuum and lawn mowing IEEE Control Systems Magazine, v27, n2, p20-23+96.
- [10] S. Dilibal, H. Şahin (2016) Endüstriyel robotlar ve tutucu sistemleri ders notları, İstanbul Gedik Üniversitesi.
- [11] http://www.ifr.org/industrial-robots/statistics/ erişim tarihi:10.03.2017.
- [12] K. Azfar, K. Pierre, G. Zied, T. Klaus-Dieter, P. Jürgen (2016) A methodology to develop collaborative robotic cyber-physical systems for production environments, Logist. Res. Springer
- [13] J. Tan, D. Feng, Y. Zhang, K. Watanabe, R. Kato, T. Arai (2009) Human-robot collaboration in cellular manufacturing: Design and development, IEEE/RSJ International Conference on Intelligent Robots and Systems.
- [14] R. Ikeura, H. Inooka (1995) Variable Impedance Control of a Robot for Cooperation with a Human, IEEE International Conference on Robotics and Automation.
- [15] E.S. Conkur ve R. Buckingham (1997) Clarifying the definition of the redundancy as used in robotics, Robotica 15, 583-586.
- [16] G. Alici, S. Dilibal, H.Sahin, C.Sozer (2016) Esnek (Soft) robotik sistemler, ToRK-2016 Türkiye Robotbilim Konferansı, Esnek Robotik Sistemler Çalıştayı, İstanbul.
- [17] S. Tepeyurt, S. Dilibal, H.Sahin (2016) Katmanlı İmalat Tekniği Kullanılarak Endüstriyel robot gripper üretimi ve operator eklem hareketleri ile manipülasyonu, ToRK-2016 Türkiye Robotbilim Konferansı, ISBN 978-6058557215.
Abstract
Collaborative
industrial robots are one of the significant technologies that have begun to
take place in the digital industry. Technological developments in industrial
robot systems have brought progress in the field of robot-human interaction.
Collaborative industrial robots, emerging as new generation industrial robots
with advanced technological sensors, actuators and control systems, actively
and passively collaborate with human and contribute to factory automation. The
use of soft robotic systems instead of rigid systems at the human-robot
interface has assisted to ensure that safety and sensitivity parameters meet
standards. In this study, a systematic analysis of collaborative robots and soft
robotic systems, which are becoming popular in the digital industry, has been
performed. Additionally, a comparison is made among existing collaborative
robots. The impedance control which is effective in the characteristic behavior
of the collaborative robots is explained. Furthermore, the concept of
collaborative robots has been investigated together with the fundamental development
concept and soft robotic systems.
References
- [1] Yeni sanayi devrimi akıllı üretim sistemleri yol haritası, TÜBİTAK Bilim, Teknoloji ve Yenilik Politikaları Daire Başkanlığı (2016).
- [2] A. Amir, G. Sascha, S. Francesca, (2016) Metrics and benchmarks in human-robot interaction: Recent Advances in cognitive robotics, Cognitive Systems Research.
- [3] C. Andrea, P. Robin, C. Andre, L. Antoine, F. Philippe (2016) Collaborative manufacturing with physical human-robot interaction, Robotics and Computer-Integrated Manufacturing, 40 1-13.
- [4] J. Krüger, T. K. Lien, A. Verl, (2009) Cooperation of human and machines in assembly lines, Manufacturing Technology, (58) 628-646.
- [5] G. Michalosa, S. Makrisa, P. Tsarouchia, T.Guaschb, D. Kontovrakisa, G.Chryssolourisa (2015) Design considerations for safe human-robot collaborative workplaces, Procedia CIRP (37) 248 – 253.
- [6] P. Akella, M. Peshkin, E. Colgate, W. Wannasuphoprasit, N. Nagesh, J. Wells, S. Holland, T. Pearson, B. Peacock (1999) Cobots for the automobile assembly line, IEEE, ICRA.
- [7] G. Michalos, S. Makris, N. Papakostas, D. Mourtzis, G. Chryssolouris (2010) Automotive assembly Technologies review: challenges and outlook for a flexible and adaptive approach, Manufacturing Technology (2) 81–91.
- [8] N. Papakostas, G. Michalos, S. Makris, D. Zouzias, G. Chryssolouris (2011) Industrial applications with cooperating robots for the flexible assembly, Int.J.Comput. Integr.Manuf. 24 (7) 650–660.
- [9] H. Sahin, and H. Guvenc (2007) Household robotics: Autonomous devices for vacuum and lawn mowing IEEE Control Systems Magazine, v27, n2, p20-23+96.
- [10] S. Dilibal, H. Şahin (2016) Endüstriyel robotlar ve tutucu sistemleri ders notları, İstanbul Gedik Üniversitesi.
- [11] http://www.ifr.org/industrial-robots/statistics/ erişim tarihi:10.03.2017.
- [12] K. Azfar, K. Pierre, G. Zied, T. Klaus-Dieter, P. Jürgen (2016) A methodology to develop collaborative robotic cyber-physical systems for production environments, Logist. Res. Springer
- [13] J. Tan, D. Feng, Y. Zhang, K. Watanabe, R. Kato, T. Arai (2009) Human-robot collaboration in cellular manufacturing: Design and development, IEEE/RSJ International Conference on Intelligent Robots and Systems.
- [14] R. Ikeura, H. Inooka (1995) Variable Impedance Control of a Robot for Cooperation with a Human, IEEE International Conference on Robotics and Automation.
- [15] E.S. Conkur ve R. Buckingham (1997) Clarifying the definition of the redundancy as used in robotics, Robotica 15, 583-586.
- [16] G. Alici, S. Dilibal, H.Sahin, C.Sozer (2016) Esnek (Soft) robotik sistemler, ToRK-2016 Türkiye Robotbilim Konferansı, Esnek Robotik Sistemler Çalıştayı, İstanbul.
- [17] S. Tepeyurt, S. Dilibal, H.Sahin (2016) Katmanlı İmalat Tekniği Kullanılarak Endüstriyel robot gripper üretimi ve operator eklem hareketleri ile manipülasyonu, ToRK-2016 Türkiye Robotbilim Konferansı, ISBN 978-6058557215.
Details
| Primary Language | Turkish |
|---|---|
| Subjects | Engineering |
| Journal Section | Articles |
| Authors | |
| Publication Date | March 13, 2018 |
| Submission Date | February 12, 2018 |
| Published in Issue | Year 2018 Volume: 2 Issue: 1 |
Cite
International Journal of 3D Printing Technologies and Digital Industry is lisenced under Creative Commons Atıf-GayriTicari 4.0 Uluslararası Lisansı