Virtual prototyping small, medium and large scale robotic arc welding cells.
Nicolescu, Adrian Florin ; Enciu, George ; Ghinea, Mihalache 等
1. INTRODUCTION
Implementation of industrial robots and the design of the robotic
arc welding cell / systems are strongly related to the
application's specificity as well as welded part's shapes
characteristics. From this point of view, a robotic arc welding cell
classification and cell structure are influenced by:
* the size (specific dimensions) and geometric configuration of the
processed parts;
* the welded joints geometry (planar / spatial as well as
parametric / non-regular curves);
* the manufacturing batch structure (number of parts per batch and
timetable / schedule) and it integration into the overall manufacturing
process scheduling all above issues being reflected in optimal selection
of:
* industrial robot location inside the application (fixed to the
ground / overlapped on a support fixed to the ground, suspended on a
fixed structure, suspended on a mobile (1/2/3 linear axis) structure;
* type and number of numerically controlled (NC) axes of the
positioner system (part orienting system during / between arc welding
stages);
* positioner system's workstation number (1/2 workstations).
Considering above mentioned aspects, the robotic arc welding cells can
be primary classified as:
* small scale systems;
* medium scale systems;
* large scale systems
each of these categories having specific subdivisions according
with robot's specific location, types / number of positioners /
workstation number (Nicolescu, 2005).
2. SMALL SCALE ROBOTIC ARC WELDING CELLS VIRTUAL PROTOTYPES
Small scale robotic arc welding cells typically include a small
size robot and a positioner having 2 workstations (***, 2009).
They are specially designed for processing small size individual /
groups of parts, having simple / complex welded joints geometry. Simple
geometry of welded joints involve limited number of positioner's NC
axes (Fig. 1a), while complex geometry of welded joints involve
increasing the number of positioner's NC axes on 2 / 3 NC axes
(Fig. 1b, c). Usually, part's arc welding having complex shape
joints is individually performed (Fig. 1c) while medium complexity shape
joints (Fig. 1b) and simple shape joints (Fig. 1a) are individually /
group performed.
Three virtual prototypes of (industrial) small scale robotic arc
welding cells including above mentioned positioners having 2
workstations with 1/2/3 NC axes are shown in Fig. 2 (Nicolescu, 2010).
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
3. MEDIUM SCALE ROBOTIC ARC WELDING CELLS VIRTUAL PROTOTYPES
Medium scale robotic arc welding cells are able to process medium
size parts of various geometrical configurations. This category of
robotic cells typically includes: two or more positioners (***, 2008),
usually up to four or six (Fig. 3) disposed on both sides of a robot
tracking module (***, 2008) in case of ground tracking robots (Fig. 4
a), or a rotating and tracking column (***, 2010) for suspended tracking
robots (Fig. 4 b). The robot / column tracking modules are used for
horizontally extending robot's working envelope (to reach all
in-line disposed positioners), while the robot / column base rotation
modules are used for allowing full robot access on two sides disposed
positioners. Ground / suspended on column location of robot is selected
accordingly part's size, respectively positioner's overall
dimensions and typically serviceability (ground tracking robots for
medium to small size part's welding and front access / operated
positioners, respectively suspended robots on column tracking modules
for medium to large parts welding and top access / operated
positioners). Higher cell's flexibility and productivity may be
reached due to greater number of (two sides, in-line) included
positioners allowing overlapping of heavy part loading and welding cycle
times (Nicolescu, 2010).
Two virtual prototypes of (industrial) medium scale robotic arc
welding cells including above mentioned components are shown in Fig. 5
(Nicolescu, 2010).
[FIGURE 3 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 5 OMITTED]
4. LARGE SCALE ROBOTIC ARC WELDING CELLS
Large scale robotic arc welding cells are designed for processing a
wide range of large size parts attached to different large size
positioners. Usually, a cell in this category include similarly
positioners as used for medium scale cells, however larger size for
allowing heavy parts robotic welding. In order to allow top access for
positioner serviceability / part welding, the robots are exclusively
suspended by mean of 3 axes gantry structure / column structures
allowing three dimensional robot's work envelope extending. Two
virtual prototypes for this cell type are illustrated in Fig. 6.
[FIGURE 6 OMITTED]
5. CONCLUSION
The paper illustrates works performed by the authors in the field
of systematic classification and virtual prototyping of robotic arc
welding cells. From classification point of view the paper has
synthesized main design features of three groups of robotic cells (small
/ medium / large scale) by tacking into account specific industrial
requirements for robotic arc welding systems. For all arc welding cell
categories virtual prototypes have been accomplished by taking into
account industrial components specific features of industrial robots,
positioners, auxiliary axes and complementary equipment.
All of these welding cells have been afterwards imported in
specific software for off-line programming and control robotic arc
welding cells, in order to test operation of designed systems
preliminary to real (industrial scale) systems configuring.
6. REFERENCES
Nicolescu, A. (2005). Industrial Robots (in Romanian), EDP Publishing House, Bucharest, Romania
Nicolescu, A. (2010). Design and Operation of Robotic Manufacturing
Systems (work in progress in Romanian), EDP Publishing House, Bucharest,
Romania
*** (2010) http://www.igm-group.com/?page_id=10--IGM products page,
Accessed on: 2010-05-17
*** (2009) http://www.abb.com/product/us/9aac910011.aspx ABB
products page, Accessed on: 2009-09-11
*** (2008) http://motoman.eu/en/Products--Motoman products page,
Accessed on: 2008-12-10
