SCARA: Difference between revisions
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SCARAs are generally faster than comparable [[Cartesian robot]] systems. Their single pedestal mount requires a small footprint and provides an easy, unhindered form of mounting. On the other hand, SCARAs can be more expensive than comparable Cartesian systems and the controlling software requires [[inverse kinematics]] for [[Linear interpolation|linear interpolated]] moves. However, this [[software]] typically comes with the SCARA and is usually transparent to the end-user. |
SCARAs are generally faster than comparable [[Cartesian robot]] systems. Their single pedestal mount requires a small footprint and provides an easy, unhindered form of mounting. On the other hand, SCARAs can be more expensive than comparable Cartesian systems and the controlling software requires [[inverse kinematics]] for [[Linear interpolation|linear interpolated]] moves. However, this [[software]] typically comes with the SCARA and is usually transparent to the end-user. |
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[[Nidec Sankyo|Sankyo Seiki]], [[Pentel]] and [[NEC]] presented the SCARA robot as a completely new concept for assembly robots in 1981. The robot was developed under the guidance of |
[[Nidec Sankyo|Sankyo Seiki]], [[Pentel]] and [[NEC]] presented the SCARA robot as a completely new concept for assembly robots in 1981. The robot was developed under the guidance of Hiroshi Makino<ref>{{Cite book|last=Wu|first=Guanglei|url=https://books.google.com/books?id=vkz2DwAAQBAJ&newbks=0&printsec=frontcover&pg=PA6&dq=hiroshi+makino+scara+robot&hl=it|title=Parallel PnP Robots: Parametric Modeling, Performance Evaluation and Design Optimization|last2=Shen|first2=Huiping|date=2020-08-08|publisher=Springer Nature|isbn=978-981-15-6671-4|language=en}}</ref> |
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, a professor at the [[University of Yamanashi]].<ref name=":0" /> Its arm was rigid in the Z-axis and pliable in the XY-axes, which allowed it to adapt to holes in the XY-axes.<ref>Assembly robot US Pat. 4,341,502 https://docs.google.com/viewer?url=patentimages.storage.googleapis.com/pdfs/US4341502.pdf</ref><ref>{{cite book|title=The Extended Arm of Man, A History of the Industrial Robot|isbn=91-7736-467-8|date=2000|first=Lars|last=Westerland}}</ref> |
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==Animations== |
==Animations== |
Revision as of 07:31, 7 October 2021
This article may need to be rewritten to comply with Wikipedia's quality standards. (March 2021) |
The SCARA is a type of industrial robot. The acronym stands for Selective Compliance Assembly Robot Arm[1] or Selective Compliance Articulated Robot Arm.[2]
By virtue of the SCARA's parallel-axis joint layout, the arm is slightly compliant in the X-Y direction but rigid in the Z direction, hence the term: Selective Compliance. This is advantageous for many types of assembly operations, i.e., inserting a round pin in a round hole without binding.
The second attribute of the SCARA is the jointed two-link arm layout similar to human arms, hence the often-used term, Articulated. This feature allows the arm to extend into confined areas and then retract or "fold up" out of the way. This is advantageous for transferring parts from one cell to another or for loading or unloading process stations that are enclosed.
SCARAs are generally faster than comparable Cartesian robot systems. Their single pedestal mount requires a small footprint and provides an easy, unhindered form of mounting. On the other hand, SCARAs can be more expensive than comparable Cartesian systems and the controlling software requires inverse kinematics for linear interpolated moves. However, this software typically comes with the SCARA and is usually transparent to the end-user.
Sankyo Seiki, Pentel and NEC presented the SCARA robot as a completely new concept for assembly robots in 1981. The robot was developed under the guidance of Hiroshi Makino[3]
- ^ "SCARA Robots - Fanuc". www.fanuc.eu. Retrieved 2021-05-27.
- ^ "The Robot Hall of Fame - Powered by Carnegie Mellon University". www.robothalloffame.org. Retrieved 2021-05-27.
- ^ Wu, Guanglei; Shen, Huiping (2020-08-08). Parallel PnP Robots: Parametric Modeling, Performance Evaluation and Design Optimization. Springer Nature. ISBN 978-981-15-6671-4.
, a professor at the University of Yamanashi.[1] Its arm was rigid in the Z-axis and pliable in the XY-axes, which allowed it to adapt to holes in the XY-axes.[2][3]
Animations
Source: [4]
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Direct kinematics of a SCARA robot
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Inverse kinematics of a 5R parallel robot
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Direct kinematics of a 5R parallel robot
See also
References
- ^ Cite error: The named reference
:0
was invoked but never defined (see the help page). - ^ Assembly robot US Pat. 4,341,502 https://docs.google.com/viewer?url=patentimages.storage.googleapis.com/pdfs/US4341502.pdf
- ^ Westerland, Lars (2000). The Extended Arm of Man, A History of the Industrial Robot. ISBN 91-7736-467-8.
- ^ Simionescu, P.A. (2014). Computer Aided Graphing and Simulation Tools for AutoCAD users (1st ed.). Boca Raton, Florida: CRC Press. ISBN 978-1-4822-5290-3.
External links
- Why SCARA? A Case Study – A Comparison between 3-axis r-theta robot vs. 4-axis SCARA robot by Innovative Robotics, a division of Ocean Bay and Lake Company