The present invention relates to a robot welding controller and a robot welding control method for operating a robot by using a consuming electrode and performing welding.
A conventional welding control method (e.g., patent literature 1) will be explained by showing
When the generation of the arc is detected from a change of a wire voltage Vw and a wire electric current Iw, a wire feed speed is set to speed Sw at a welding time from time t3, and a steady welding state is started.
Patent literature 1: JP-A-2002-160059 (line 40 of left-hand column of page 4 to line 5 of right-hand column of page 4)
However, in the above-mentioned conventional robot controller, a problem exists in that the welding becomes unstable at an initial stage for starting the welding of the steady state after the arc generation.
The present invention is intended to solve such a problem caused in the conventional construction, and its object is to provide a robot welding controller and a robot welding control method for realizing welding of high quality by using a robot.
According to claim 1, there is provided a robot welding controller for welding by moving a welding torch on the basis of a welding line commanded in advance including:
a robot having the welding torch at a tip thereof,
a robot controller for controlling the operation of the robot;
a wire feeder for feeding a wire to the welding torch;
a welding electric power source for supplying electric power between the wire and a base material;
a contact detecting section for detecting contact of the wire and the base material;
a feed direction switching section for switching feed directions of the wire;
an arc generation detecting section for detecting that an arc is generated between the wire and the base material;
a waveform control section for controlling electric power waveforms of plural shapes applied between the wire and the base material; and
a welding sequence section for controlling the operations of the contact detecting section, the feed direction switching section, the arc generation detecting section and the waveform control section in block.
According to claim 2, there is provided the robot welding controller, wherein
the electric power waveforms of the plural shapes include the waveform of a pulse shape.
According to claim 3, there is provided the robot welding controller, wherein
a parameter variable for controlling the electric power waveforms of the plural shapes is set from the robot controller.
According to claim 4, there is provided a robot welding control method for welding by moving a welding torch on the basis of a welding line commanded in advance with a robot including a welding torch at a tip thereof, a robot controller for controlling the operation of the robot, a wire feeder for feeding a wire to the welding torch, and a welding electric power source for supplying electric power between the wire and a base material,
the robot welding control method including:
a step for feeding the wire applying a voltage thereto;
a step for judging that the wire comes in contact with the base material;
a step for feeding the wire in a reverse direction;
a step for judging that an arc is generated between the wire and the base material;
a step for supplying electric power to the wire by a first waveform while the wire is fed in a normal direction; and
a step for supplying the electric power by a second waveform different from the first waveform after a predetermined time has passed.
According to claim 5, there is provided the robot welding controller, wherein
the first waveform is the waveform of a pulse shape.
According to claim 6, there is provided the robot welding controller, wherein
a parameter variable for controlling the first waveform and the second waveform is set from the robot controller.
In accordance with the present invention, since the arc is reliably generated and can be then stabilized, it can rapidly proceed to a welding main condition.
1 robot
2 torch
3 wire feeder
5 robot controller
10 welding electric power source
11 feed driving section
12 feed direction switching section
13 arc generation detecting section
14 electric current detecting section
15 voltage detecting section
16 contact detecting section
20 welding sequence section
21 electric power supply section
22 waveform control section
30 wire storing section
Embodiment modes of the present invention will next be explained on the basis of
A system constructional view of the present invention is shown in
A welding electric power source 10 has a feed driving section 11 for controlling the operation of the electric motor of this wire feeder 3. Electric power of welding is supplied from an electric power supply section 21 within the welding electric power source 10. A waveform control section 22 controls a welding waveform outputted from the electric power supply section 21.
Further, the welding electric power source 10 has an electric current detecting section 14 and a voltage detecting section 15 for detecting an output state during welding. An arc generation detecting section 13 detects that an arc is generated on the basis of the electric current detecting section 14 and the voltage detecting section 15.
Subsequently, processing of a welding sequence section 20 is shown in detail on the basis of
The robot 1 is moved to a welding starting point. Thereafter, a welding condition and a welding starting command are outputted from the robot controller 5 to the welding electric power source 10.
In the welding electric power source 10, the welding sequence section 20 executes polling processing with respect to the command from the robot controller 5. This polling period is shorter than a control period of the robot controller 5.
When the welding sequence section 20 recognizes the welding starting command from the robot controller 5 by the polling processing, a command is given to the feed driving section 11 so as to rotate the electric motor of the wire feeder 3 in a normal direction. At this time, a command is simultaneously given to the electric power supply section 21 so as to apply a predetermined voltage between the wire and a base material.
A contact detecting section 16 monitors an output voltage by the voltage detecting section 15 while the wire is fed and controlled in the normal direction. When the output voltage becomes a predetermined value or less, it is judged that the wire comes in contact with the base material, and the contact is notified to the welding sequence section 20. When the welding sequence section 20 receives the notification of the contact detection of the wire, the welding sequence section 20 gives a command to a feed direction switching section 12 so as to switch feed directions. The feed direction switching section 12 gives commands to the feed driving section 11 so as to once stop the wire feed and then feed the wire in the reverse direction. Thus, the wire is returned in a direction separated from the base material (in the reverse direction).
While the wire is returned in the direction separated from the base material, an output electric current is detected in the electric current detecting section 14. The arc generation detecting section 13 monitors the output electric current from the electric current detecting section 14, and judges that an arc is generated when the output electric current becomes a predetermined value or more. When the arc generation detecting section 13 judges that the arc is generated, the arc generation detecting section 13 notifies the arc generation to the welding sequence section 20.
The welding sequence section 20 gives a command to a waveform control section 22 so as to control welding by a first waveform. The waveform control section 22 receiving the command executes welding by the first waveform. When the welding sequence section 20 executes the welding of the first waveform for a predetermined time, the welding sequence section 20 gives a command to the waveform control section 22 so as to execute welding by a second waveform.
The first waveform and the second waveform are shown in
After the arc generation, the first waveform is controlled so as to become a pulse waveform to stabilize welding for a predetermined time. When the wire is transferred to a melting droplet by the pulse waveform, the welding of a small spatter can be performed by controlling the size of this melting droplet.
Thus, if the welding waveform is controlled in a pulse shape during a constant time from an arc welding start, the arc can be reliably stabilized and a preferable arc start can be made. It can then rapidly proceed to a welding main condition by reliably making the arc start.
Further, if patterns of the first waveform and the second waveform are recognized by numbers, various welding waveforms at a welding starting time can be controlled by giving commands of the pattern numbers from the robot controller 5.
Further, in this embodiment, management is performed by passage time with respect to switching of each waveform. However, timing of the switching may be also made by various parameters such as average electric current value, voltage value, etc.
The present invention is useful in a robot welding controller and a robot welding control method for performing welding by using a consuming electrode.
Number | Date | Country | Kind |
---|---|---|---|
2004-170011 | Jun 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2005/009374 | 5/23/2005 | WO | 00 | 3/6/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2005/120758 | 12/22/2005 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4560857 | Segawa et al. | Dec 1985 | A |
6207928 | Kawamoto et al. | Mar 2001 | B1 |
6534746 | Yamamoto et al. | Mar 2003 | B1 |
20040074885 | Takatani et al. | Apr 2004 | A1 |
Number | Date | Country |
---|---|---|
03297564 | Dec 1991 | JP |
2000-670 | Jan 2000 | JP |
2002-160059 | Jun 2002 | JP |
2002-205169 | Jul 2002 | JP |
WO 0103875 | Jan 2001 | WO |
WO 02066194 | Aug 2002 | WO |
Number | Date | Country | |
---|---|---|---|
20080041834 A1 | Feb 2008 | US |