Paper Titles

Analysis of Design Today Exoskeletons in the Health Field
p.320

Simulation of Collision Situations in RobotStudio
p.325

Modelling of Dynamic System Characteristics of Deep Hole Drilling Process with Tools about Flexible Stifness
p.333

The Solar Tracker – A Control System and a Frame Construction
p.340

On Line Videooptical System for Weld Groove Analysis
p.350

Accuracy Control in the Machining of Low Rigidity Shafts
p.357

Some Aspects of Interoperability of Enterprise and Manufacturing Systems
p.368

New Standard in Scanning of Welding Electrodes by Using Visualization
p.379

Application of Hot Gas Powder Sintering in Robotics
p.386

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 613On Line Videooptical System for Weld Groove...

On Line Videooptical System for Weld Groove Analysis

Article Preview

Abstract:

The article shows the video-optical system for to recognition of location and size of weld groove. Was used special system equipped with two USB cameras (VGA resolution) and red laser laser. First of camera was used to recognition of groove location and second one with laser as mobile scanner was used to size of groove analyse. For proposed conception was prepared in Visual Basic 6.0 special software WELD_REC, which calculate the angle of groove location and the groove parameters: width, depth and angle of opening. Presented system is used for experiments using PC controlled IRb –60 industrial robot. The differences of location of groove: between well-known and video-optical measured have the highest of 3% .

You might also be interested in these eBooks

Industrial and Service Robotics

Info:

Periodical:

Applied Mechanics and Materials (Volume 613)

Pages:

350-356

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.613.350

Citation:

Cite this paper

Online since:

August 2014

Authors:

Tadeusz Mikolajczyk*, Mikolaj Mikolajczyk, Andrzej Skibicki

Keywords:

Intelligent Robot Control, Picture Recognition, Weld Groove

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2014 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] Mikolajczyk T., Modernisation of IRb60 industrial robot steering system. OPTIROB'2007, Predeal Romania, University POLITEHNICA, of Bucharest, 149-152.

[2] bEuropean Commssion Report, 2003. Smart, Sustainable Manufacturing: EU Research Sparks Revolution in Machine Tools, Robots and Automation, Research and Innovation Report, Brussels, (2003).

[3] Mikołajczyk T., Nowicki K.: Ocena obrazu zużycia ostrza z wykorzystaniem sieci neuronowych. (Recognition of Edge Wear Using Neural Networks). Mechatronika, Warszawa, 1997, 829-833.

[4] Mikolajczyk T., The Robot Machining System with Surface Shape Active Control. OPTIROB'2007, Predeal Romania, University POLITEHNICA, of Bucharest, 205-209.

[5] Stanciu M., Popa S., Ristea A., Intelligent vision system for grasping error compensation of a wafer manipulation robot. OPTIROB'2006, Predeal-Romania University POLITEHNICA, of Bucharest, ROMANIA, 203-206.

[6] Mikolajczyk T., Videooptical Surface Shape and Integrity Estimation in Robots Machining, Applied Mechanics and Materials, vol. 332, (2013), 431-436.

DOI: 10.4028/www.scientific.net/amm.332.270

[7] Mikolajczyk T., System to Surface Control in Robot Machining. Advanced Materials Research Vols. 463-464 (2012), 708-711.

DOI: 10.4028/www.scientific.net/amr.463-464.708

[8] Mikolajczyk T., Wasiak P., Machining With Image Recognition Using Industrial Robot. Applied Mechanics and Materials, Vol. 186 (2012), 50-57.

DOI: 10.4028/www.scientific.net/amm.186.50

[9] Mikołajczyk T., Zastosowanie analizy obrazu w badaniach obiektów i procesów (Implementation of Picture Analysis in Research of Objects and Process), Diagnostyka, vol. 33, (2005), 123-128 (in polish).

[10] Mikolajczyk T., Polasik R., High Temperature Diagnosis with Infrared CMOS Camera. Journal of Polish CIMAC, vol. 6, no 2, (2011), 161-167.

[11] Mikolajczyk T., Olaru A., Krainski P., Adaptive Control System for Drill Machine. Applied Mechanics and Materials, 2013, vol. 436, pp.445-450.

DOI: 10.4028/www.scientific.net/amm.436.445

[12] Mikolajczyk T., Manufacturing Using Robot. Advanced Materials Research, vol. 463-464, (2012), 1643-1646.

DOI: 10.4028/www.scientific.net/amr.463-464.1643

[13] Mikolajczyk T., Romanowski L., Indication of Machining Area with the Robot's Camera Using, Applied Mechanics and Materials, vol. 282 , (2013), 146-151.

DOI: 10.4028/www.scientific.net/amm.282.146

[14] Mikołajczyk M., Mikołajczyk T., Skibicki A., Intelligent System for Diagnostics of Weld Groove. III Int. Conference Optimization of the Robots and Manipulators OPTIROB'2008. Predeal, Romania, 2008 Bren Publishing House, 261-265.

[15] Semjon J., Hajduk M., Jánoš R., Vagaš M.: Modular Welding Fixtures for Robotic Cells / - 2013. In: Applied Mechanics and Materials. Vol. 309 (2013), pp.80-87.

DOI: 10.4028/www.scientific.net/amm.309.80

[16] Baláž V., Vagaš M., Semjon J., Hajduk M.: Design of automated robotized system with two robots / - 2013. In: Computer Aided Production Engineering. - Lublin : Lublin University of Technology, 2013 P. 131-136.

[17] Sukop M., Hajduk M., Varga J., Vagaš M.: Image processing and object founding in the robot soccer application / - 2012. In: International Scientific Herald. Vol. 3, no. 2 (2012), pp.203-206.

[18] Baláž V., Vagaš M., Semjon J., Hajduk M., Koukolová L.: Metodický rámec navrhovania štruktúr paletizačno-montážnych robotických buniek /- 2013. In: Robotics and Intelligent Manufacturing Systems : zborník príspevkov z medzinárodnej konferencie : 27. jún 2013, Košice. - Košice : TU, 2013 s. 93-98.