JP3367034B2 - High voltage generation system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high voltage generating system for starting an arc of a consumable electrode type pulse arc welding machine for automatically feeding and welding a wire.

[0002]

2. Description of the Related Art In recent years, consumable electrode type pulse arc welding is one of important processing means, and a stable starting operation thereof is required.

A conventional high voltage generating system will be described below. The conventional high-voltage arc start method generates a spark discharge with a predetermined high voltage between the base material and the electrode when the arc is started, and the insulating material (slag as an example) at the tip of the wire is generated by the electric shock of the generated spark discharge. It breaks and induces an arc. However, in order to improve the success rate of the arc start, as shown in FIG. 12, a high voltage generator 6 for generating a high voltage is provided, and when the welding is started, the welding voltage generated by the welding power source 5 is set to the above-mentioned value. The predetermined high voltage of the high voltage generator 6 is superimposed to cause spark discharge, and the high voltage is stopped when the arc current is detected. In FIG. 12, 1
Is a welding wire, 2 is a wire feeding motor, 3 is an electrode,
4 is a base material.

[0004]

In such a conventional means, a predetermined constant high voltage is applied regardless of the size of the insulating material. The arc start becomes difficult depending on the state, and if the state where the arc start is difficult continues to occur for each welding, the success rate of the arc start is lowered.

When restarting on the crater after welding is completed, the arc startability is further deteriorated due to the slag generated on the crater. In order to prevent the deterioration of arc startability, the applied voltage can be set to a very large value so that all insulating materials can be destroyed. Since the deterioration of the insulating material for cutting off the electric field progresses and the worker is exposed to danger, the insulating material for protecting the worker must be strengthened, and the workability,
There is a problem with maintainability.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a high voltage generation system which realizes good arc start performance adapted to welding conditions.

[0007]

The present invention SUMMARY OF THE INVENTION To achieve the above object, the present invention relating to claim 1, the wire diameter and the instruction input, as a voltage value adapted to the indicated wire diameter
It is a high voltage generation system which automatically switches and sets to a value at which the insulating material at the tip of the wire is destroyed .

As a result, a high voltage suitable for the wire used can be output, and the arc start success rate can be improved.

The present invention according to claim 2 is a high voltage generating system for monitoring an arc break state with respect to a predetermined set voltage value and automatically switching and setting in accordance with the arc cut state.

As a result, a realistic high voltage can be output based on the arc state, and the arc start success rate can be further improved.

According to a third aspect of the present invention, the high voltage for centrally controlling a plurality of welding machines so as to monitor an arc break state with respect to a predetermined set voltage value and switch and set the voltage value corresponding to the arc break. It is a generation system.

With this, the high voltage of each of the plurality of welding machines is centrally controlled so that the high voltage is switched and set based on the arc cut state with respect to each predetermined set voltage value. Therefore, similar to the means according to claim 2, Each can make a good arc start, and if the conditions of each welder are the same, the appropriate conditions of one unspecified welder can be applied to other welders to start the arc of another welder. The success rate can also be improved.

According to a fourth aspect of the present invention, there is provided a high voltage generating system for observing an arc break state with respect to a predetermined set voltage value adapted to an indicated welding current value, and automatically switching and setting in accordance with the arc break state. is there.

With this, the voltage value is determined based on the arc state with respect to the predetermined set voltage value adapted to the welding condition, so that the accuracy is higher and the arc start success rate can be further improved.

According to a fifth aspect of the present invention, for a plurality of welding machines, the arc break state is monitored for a predetermined set voltage value adapted to the indicated welding current value, and the voltage value is switched and set according to the arc cut state. It is a high voltage generation system that performs centralized control so that

Thus, the high voltage of each of the plurality of welding machines is centrally controlled so as to be switched and set based on the arc break state with respect to a predetermined set voltage value adapted to each welding condition. Similar to the means, each can make a good arc start, and if the conditions of each welder are the same, the appropriate condition of one unspecified welder can be applied to other welders as well. The arc start success rate of the welding machine can also be improved.

According to the present invention of claim 6, when welding is started ,
High voltage that destroys the insulating material at the tip of the wire, at the end of welding
It is a high voltage generation system that applies a high voltage that destroys the insulating material on the crater .

This makes it possible to start an arc at the start of welding and destroy the crater at the end of welding to facilitate the next arc start.

[0019] The present invention relating to claim 7, wire as a high voltage wire diameter and instruction input, adapted to instruct the wire diameter
A high voltage that destroys the insulating material at the tip of the
A high voltage to destroy the insulating material on the rater is a high voltage generating system adapted to mark <br/> pressure at the end of welding.

As a result, a high voltage suitable for the wire diameter can be applied at the start of welding and at the end of welding, and the success rate of arc start can be further improved.

The present invention according to claim 8 monitors the arc cut state with respect to a predetermined set voltage value, automatically sets the switching in accordance with the arc cut state, and outputs at the start of welding and the end of welding. It is a high voltage generation system.

Thus, a realistic high voltage based on the arc state can be output at the start of welding and at the end of welding, and the success rate of arc start and restart can be further improved.

According to a ninth aspect of the present invention, with respect to a plurality of welding machines, the arc breaking state with respect to a predetermined set voltage value is monitored, and the voltage value is switched and set according to the arc breaking state. It is a high-voltage generation system that performs centralized control so that it is output at the time of termination.

As a result, the high voltage of each of the plurality of welding machines is automatically switched and set based on the state of arc breakage with respect to each predetermined set voltage value, and is output at the start of welding and at the end of welding. Since centralized control is performed, like the means according to claim 8, each can perform good arc start and restart, and if the conditions of each welder are the same, an unspecified one welder is suitable. Such conditions can be applied to other welding machines to improve the success rate of arc start.

According to the tenth aspect of the present invention, the arc break condition for a predetermined set voltage value adapted to the indicated welding current value is monitored, and the voltage value at the start of welding is automatically switched according to the arc break condition. This is a high voltage generation system that sets and switches the voltage value at the end of welding to a voltage value suitable for restart, and generates a high voltage at the start of welding and at the end of welding.

As a result, a realistic high voltage based on the arc state is output at the start of welding and a high voltage suitable for restart is output at the end of welding, so that the success rate of arc start and restart can be further improved. You can

According to the present invention of claim 11, at the start of welding, the arc breaking state for a predetermined set voltage value adapted to the indicated welding current value is monitored for a plurality of welding machines, and the voltage value corresponding to the arc breaking state. This is a high voltage generation system that performs centralized control so that the voltage value is switched and set at the end of welding and switched to a voltage value adapted to restart.

Thus, the high voltage of each of the plurality of welding machines is switched and set based on the arc break state with respect to the predetermined set voltage value adapted to each welding condition at the start of welding and adapted to restart at the end of welding. Since the centralized control is performed so as to switch and set the voltage values, the same arc start and restart can be performed as in the means according to claim 10, and if the conditions of each welding machine are the same. It is possible to improve the arc start success rate of other welding machines by applying the appropriate conditions for one unspecified welding machine to other welding machines.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION The wire diameter input means is a means for the user to input a numerical value for the diameter of the welding wire and to control it so as to switch and set it to a high voltage value adapted to the value. The switching control is performed by outputting a switching signal corresponding to the wire diameter to the switching high voltage generating means.

The arc breakage monitoring means is a means for monitoring the arc breakage between the wire and the welding base metal, and the arc breakage state with respect to a predetermined set voltage value or a predetermined set voltage value adapted to the indicated welding current value indicates the welding current. The waveform is monitored during a predetermined period and the monitoring result is output.

Also, monitoring type control means, current-monitoring type control means, plural monitoring type control means,
Multiple current - monitoring type controller, multiple double applied current - monitoring control means, the voltage value switching of the high voltage generating unit by outputting a switching signal corresponding to the voltage value to switch each switchable high voltage generating means To control.
The double applied current-monitoring control means and the plural double applied current-monitoring control means according to claims 10 and 11 are set to switch and set different voltage values at the start of welding and at the end of welding. , after setting switched at the start welding, but so as to instruct the switching voltage at the welding end by a request signal from the high-voltage pressure generating means, but is not limited to this means.

It should be noted that each switching type high voltage generating means is realized by a conventional means, and it should not be mentioned specially.

Examples will be described below.

[0034]

【Example】

(Embodiment 1) Hereinafter, Embodiment 1 of the high voltage generation system of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of this embodiment. In the figure, 1 is a welding wire and 2 is a wire 1.
A wire feeding motor for feeding the welding material to the welding portion of the base material 4, 3 is an electrode for giving the output of the welding power source 5 to the wire 1, 8
Is a welding current indicator for indicating a welding current value, 9 is a wire diameter input device for instructing and inputting the diameter of the wire 1 (hereinafter referred to as wire diameter) by an operator or the like, and outputting a switching signal corresponding to the wire diameter, Reference numeral 10 denotes a switching type high voltage generator that generates a high voltage whose voltage value can be switched. The switchable high voltage generator 10 has a function of not being able to output a high voltage for an unnecessarily long time by a timer or current detection.

The operation of the above configuration will be described. The welding current value necessary for welding is instructed to the welding power source 5 by the welding current indicator 8. The wire diameter input device 9 switches the voltage value of the high voltage of the switchable high voltage generator 10 according to the wire diameter currently used, and switches to the output of the welding power source 5 in response to the welding start signal. The high voltage output from the high voltage generator 10 is applied.

By the above operation, since a high voltage adapted to the wire diameter is output, the insulating material at the tip of the wire 1 is easily destroyed, and the arc start performance is improved and improved as compared with the conventional high voltage application method. To be done.

(Second Embodiment) A second embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is a block diagram showing the configuration of this embodiment. The same components as those of the first embodiment shown in FIG. 1 are assigned the same reference numerals and detailed explanations thereof will be omitted. The present invention is different from the embodiment in that an arc break monitor 11 and a monitoring type controller 12 are provided, the arc break is monitored, and the switching type high voltage generator 10 is automatically operated based on the arc break condition. The purpose is to switch the output voltage to an appropriate value and set it. In the figure, 7 is a current detector for detecting a welding current, 11 is an arc breakage monitor for monitoring the arc breakage state based on the waveform of the welding current, and 12 is a switching type high voltage corresponding to the monitoring result of the arc breakage monitor 11. It is a monitoring type controller that generates and outputs a switching signal for switching the voltage of the voltage generator 10.

The operation of the above configuration will be described. Similar to the first embodiment, the welding current indicator 8 indicates the welding current value required for welding to the welding power source 5, and the welding power source 5 is set. Further, the monitoring controller 12 first sets the voltage value of the high voltage of the switching high voltage generator 10 to a predetermined value.
The switchable high voltage generator 10 generates the predetermined voltage value, and in response to the welding start signal, the predetermined high voltage is superimposed on the output of the welding power source 5 to perform arc start. From this time point, the arc breakage monitor 11 monitors the arc breakage state by the welding current waveform detected by the current detector 7 for a predetermined period. The monitoring type controller 12 analyzes the arc breaking state, selects an appropriate high voltage voltage value, generates a switching signal corresponding to it, and outputs it to the switching type high voltage generator 10 to output the switching type high voltage generator. Reference numeral 10 switches from the predetermined voltage value to a voltage value given by a switching signal to generate a high voltage,
Output.

By the above operation, by switching and setting to the high voltage determined based on the arc cut state,
It is possible to apply an appropriate high voltage that matches the actual situation, the insulating material at the tip of the wire 1 is easily destroyed, and the arc start performance is improved or improved as compared with the conventional high voltage application method.

(Third Embodiment) A third embodiment of the present invention will be described below with reference to the drawings. FIG. 3 is a block diagram showing the configuration of this embodiment. The same components as those in the second embodiment shown in FIG. 2 are assigned the same reference numerals and detailed explanations thereof will be omitted. The present embodiment differs from the second embodiment in that a plurality of welding machines including a plurality of monitoring type controllers 13 and an arc break monitor 11, a switching type high voltage generator 10, a welding power source 5 and the like are used. The control similar to the above is centrally controlled by the plural monitoring type controller 13. In addition, the plural monitoring type controller 13 is not specified 1
The appropriate conditions of the table can be reflected to other welding machines.

The operation of the above configuration will be described. The plural monitoring type controller 13 is an arc breakage monitor 1
1. Input the monitoring result from each arc break monitor of multiple sets of welding machines equipped with switching type high voltage generator 10, welding power source 5, etc., and select an appropriate voltage value according to the monitoring result. Then, a corresponding switching signal is generated and output to each switching high voltage generator. Therefore, as in the second embodiment, an appropriate high voltage is automatically applied to each welding machine, and a good arc start is executed.

When the welding conditions of the plurality of welding machines are equal to each other, the appropriate switching setting condition obtained by one unspecified welding machine is immediately transferred to the other switching high voltage generator 10. Can be reflected. Therefore, it is possible to operate efficiently because there is no need to set the switching for those welding machines.

With the above operation, a plurality of welding machines can perform good arc start, and when the welding conditions of the plurality of welding machines are the same, common problems can be solved by one welding machine. It is also possible to apply to, and efficient operation is possible.

(Embodiment 4) Hereinafter, Embodiment 4 of the present invention will be described with reference to the drawings. FIG. 4 is a block diagram showing the configuration of this embodiment. The same components as those in the second embodiment are assigned the same reference numerals and detailed explanations thereof will be omitted. In the figure, 14 is a current for switching and setting the switchable high voltage generator 10 based on the predetermined set voltage value set corresponding to the instruction current value set by the welding current indicator 8 and the monitoring result of the arc break monitor 11. -It is a monitoring type controller.
The present embodiment is different from the second embodiment in that the predetermined voltage value initially set in the second embodiment is replaced with a predetermined value adapted to the indicated welding current value set by the welding current indicator, and the actual welding is performed. This is because the voltage value is switched and set based on the state of arc breakage with respect to the set voltage value approaching the condition.

The operation of the above configuration will be described. The welding current indicator 8 indicates the welding current value required for welding to the welding power source 5, and the current-monitoring type controller 1
Also instruct 4. The current-monitoring type controller 14 is
First, the switchable high voltage generator 10 is instructed to generate a predetermined voltage value adapted to the indicated welding current value. The switching high voltage generator 10 outputs a high voltage of the predetermined voltage value in response to the welding start signal, and the arc start is started. At this time, the arc break monitor 11 monitors the arc break condition for a predetermined period, and the result is monitored by the current-monitoring controller 14
Output to. The current-monitoring type controller 14 selects an appropriate voltage value from the state of arc interruption, outputs a switching signal corresponding to the voltage to the switching high voltage generator 10, and switches and sets the voltage value. Since the voltage value thus switched and set is based on the predetermined voltage value approaching the welding conditions, it can be said that the voltage value is more accurate than the voltage value set from the predetermined voltage value in the second embodiment.

By the above operation, a more appropriate high voltage is applied, so that a better arc start can be performed and the success rate of arc start can be further increased.

(Fifth Embodiment) A fifth embodiment of the present invention will be described below with reference to the drawings. FIG. 5 is a block diagram showing the configuration of this embodiment. The same components as those of the fourth embodiment shown in FIG. 4 are assigned the same reference numerals and detailed explanations thereof will be omitted. In the figure, reference numeral 15 is a multi-current-monitoring type controller for centrally controlling arc start of a plurality of welding machines. The present embodiment is different from the fourth embodiment in that a plurality of current-monitoring type controllers 15 are provided and the same operation as that of the fourth embodiment is centrally controlled for a plurality of welding machines. In addition, the monitoring results of one unspecified unit will be reflected to other welding machines.

The operation of the above configuration will be described. Similar to the fourth embodiment, a plurality of welding machines are respectively provided with a welding current indicator 8, a switching type high voltage generator 10, and an arc breakage monitor 1.
1, the multi-current-monitoring type controller 15 selects an appropriate voltage value from the arc disconnection state at a predetermined set voltage value adapted to each indicated welding current value, and switches each to generate that voltage. A switching signal is output to the high-voltage generator to set the switching. When the welding conditions of a plurality of welding power sources are the same, the voltage value switched and set for one welding machine is applied to another welding machine.

By the above operation, the switching settings can be centrally controlled so that a plurality of welders can perform good arc start, and a problem such as arc breakage at the time of arc start in a plurality of welders under the same welding conditions can be reduced.
It is possible to solve common problems depending on the solution conditions of the welding machine of the table, and it is possible to operate efficiently.

(Sixth Embodiment) A sixth embodiment of the present invention will be described below with reference to the drawings. FIG. 6 is a block diagram showing the configuration of this embodiment. The same components as those of the first embodiment shown in FIG. 1 are assigned the same reference numerals and detailed explanations thereof will be omitted. In the figure, reference numeral 16 is a dual-application high voltage generator that outputs a predetermined high voltage in response to a welding start signal and outputs a predetermined high voltage in response to a welding end signal. The double-applied high voltage generator 16 has a function of not being able to output a high voltage for a longer time than necessary by a timer or current detection. Note that this embodiment is the first embodiment.
The difference from Example 5 is that a high voltage is generated and output at the start of welding and at the end of welding, an arc is started by the high voltage at the start of welding, and a crater is destroyed by the high voltage at the end of welding. The next arc start is made easier.

The operation of the above configuration will be described. The double-application high voltage generator 16 superimposes a predetermined high voltage on the output of the welding power source 5 in response to the welding start signal to start an arc. Further, the predetermined high voltage is output again in response to the welding end signal.

By the above operation, good arc start is performed by the high voltage at the start of welding, and the insulating material at the tip of the wire 1 and the insulating material on the crater are destroyed by the high voltage at the end of welding, and the arc on the crater is destroyed. The restart can be facilitated and the success rate of arc start can be improved.

(Embodiment 7) Embodiment 7 of the present invention will be described below with reference to the drawings. FIG. 7 is a block diagram showing the configuration of this embodiment. The same components as those of the first embodiment shown in FIG. 1 are assigned the same reference numerals and detailed explanations thereof will be omitted. The present embodiment is different from the first embodiment in that the switching type high voltage generator 10 is replaced with a switching type double application type high voltage generator 17 which outputs a high voltage at the start of welding to start an arc. The purpose is to output a high voltage even after welding is completed. The other operation is the same as that of the first embodiment, and the description is omitted.

With the above operation, a high voltage suitable for the wire diameter can be output to achieve a good arc start, and the high voltage can be output even at the end of welding. It destroys the insulating material on the crater, making it easier to restart on the crater.

(Embodiment 8) An embodiment 8 of the present invention will be described below with reference to the drawings. FIG. 8 is a block diagram showing the configuration of this embodiment. The same components as those in the second embodiment shown in FIG. 2 are assigned the same reference numerals and detailed explanations thereof will be omitted. The present embodiment is different from the second embodiment in that the switching high voltage generator 10 is replaced by a switching double-applying high voltage generator 17, and as in the second embodiment, a predetermined set voltage value and an arc break. The high voltage switched according to the state is output at the start of welding and at the end of welding. The other operation is the same as that of the second embodiment, and the description is omitted.

By the above operation, a good arc start is made at the start of welding, the insulating material at the tip of the wire 1 and the insulating material on the crater are destroyed, and restart on the crater is facilitated, and the arc start is successful. The rate can be further improved.

(Ninth Embodiment) A ninth embodiment of the present invention will be described below with reference to the drawings. FIG. 9 is a block diagram showing the configuration of this embodiment. The same components as those in the eighth embodiment shown in FIG. 8 are designated by the same reference numerals, and detailed description thereof will be omitted. In the figure, 13 is a multi-monitoring type controller for centrally controlling the arc start of a plurality of welding machines. The present embodiment is different from the eighth embodiment in that a plurality of monitoring type controllers 13 are provided and the plurality of welding machines are used in the eighth embodiment.
This is because the same operation as in (4) is controlled centrally. In addition, the monitoring results of one unspecified unit will be reflected to other welding machines.

The operation of the above configuration will be described. Similar to the eighth embodiment, a plurality of welding machines are respectively provided with a welding current indicator 8, a switching type double application type high voltage generator 17 and an arc break monitor 11, and a plurality of monitoring type controllers 13 are provided.
Selects an appropriate voltage value from the arc cut-off state at each predetermined set voltage value, outputs a switching signal to each switching type double application type high voltage generator so as to generate that voltage, and performs switching setting. . When the welding conditions of a plurality of welding power sources are the same, the voltage value switched and set for one welding machine is applied to another welding machine.

With the above operation, the switching settings can be centrally controlled so that a plurality of welders can each perform a good arc start, as in the case of the eighth embodiment, and an arc is started at the time of arc start in a plurality of welders under the same welding conditions. Problems such as disconnection can be commonly solved under the solution conditions of one welding machine, and efficient operation can be performed.

Example 10 Hereinafter, Example 10 of the present invention will be described.
Will be described with reference to the drawings. FIG. 10 is a block diagram showing the configuration of this embodiment. The same components as those in the eighth embodiment shown in FIG. 8 are designated by the same reference numerals, and detailed description thereof will be omitted. In the figure, 18 is a switching type double application notification type high voltage generator for generating a voltage value at the start of welding and a voltage value at the end of welding by switching signals, and 19 is a welding current indicator 8 at the start of welding. Is a dual applied current-monitoring controller for switching and setting a selected voltage value from a state of arc breakage with respect to a predetermined set voltage value adapted to the indicated current value, and switching and setting a high voltage value at the end of welding. The present embodiment differs from the eighth embodiment in that a switching type double application type high voltage generator 17 is provided with a switching type double application notification type high voltage generator 18, and a monitoring type controller 12 is used instead. A double applied current-monitoring controller 19 is provided, a predetermined voltage value adapted to the indicated welding current value is set instead of the predetermined set voltage value, and the voltage value at the start of welding and the voltage value at the end of welding are different. It is possible to switch and set the value.

The operation of the above configuration will be described. The welding current indicator 8 indicates the welding current value necessary for welding to the welding power source 5 and the double applied current-monitoring controller 19. The dual applied current-monitoring controller 19
First, select the set voltage value that is suitable for the indicated welding current value,
The switching type double application notification type high voltage generator 18 is set. The switchable double application notification type high voltage generator 18 generates and outputs the predetermined set voltage value in response to a welding start signal. At this time, the arc break monitor 11 monitors the arc break for a predetermined period and outputs the monitoring result to the double applied current-monitoring controller 19. The double applied current-monitoring controller 19 analyzes the monitoring result, selects an appropriate high voltage value, and switches and sets the voltage of the switchable double applied notification type high voltage generator 18 by a switching signal. Upon completion of this switching setting, the switching double application notification type high voltage generator 18 requests the double applied current-monitoring controller 19 with a request signal for the voltage value to be switched and set at the end of welding. In response to the request signal, the double applied current-monitoring controller 19 gives a voltage value to be switched and set at the end of welding to the switchable double applied notification type high voltage generator 18 by a switching signal. The switching type double application notification type high voltage generator 18 switches to the voltage value at the end of welding and outputs it in response to the welding end signal. The high voltage value at the end can be set to another value independent of the high voltage value for arc start, so as to be suitable for breaking the insulating material on the wire tip and the crater.

By the above operation, good arc start can be performed, and at the end, the insulating material at the tip of the wire and the insulating material on the crater are more effectively destroyed, and the restart on the crater becomes easier and the arc start The success rate can be further improved.

(Embodiment 11) Hereinafter, Embodiment 11 of the present invention will be described.
Will be described with reference to the drawings. FIG. 11 is a block diagram showing the configuration of this embodiment. The same components as those of the tenth embodiment shown in FIG. 10 are assigned the same reference numerals and detailed explanations thereof will be omitted. In the figure, 20 is a plurality of double applied currents for centralized control of arc start of a plurality of welding machines-
It is a monitoring controller. This embodiment is different from the tenth embodiment in that a plurality of double applied currents-monitoring controller 20 is used.
And the same operation as that of the tenth embodiment is centrally controlled for a plurality of welding machines. In addition, the monitoring results of one unspecified unit will be reflected to other welding machines.

The operation of the above configuration will be described. Similar to the tenth embodiment, a plurality of welding machines are respectively provided with a welding current indicator 8, a switching type double application notification type high voltage generator 18 and an arc breakage monitor 11, and a plurality of double application current-monitoring control. The generator 20 selects an appropriate voltage value from the arc break state at a predetermined set voltage value adapted to each indicated welding current value, and each switchable double application notification type high voltage generator so as to generate that voltage value. A switching signal is output to set the switching, and the voltage value at the end of welding is instructed in response to the request signal of each switching type double application notification type high voltage generator. When the welding conditions of a plurality of welding power sources are the same, the voltage value switched and set for one welding machine is applied to another welding machine.

With the above operation, a plurality of welders can centrally control the switching settings so that a good arc start and restart can be performed, respectively, as in the tenth embodiment, and in a plurality of welders under the same welding conditions. Problems such as arc breakage at the time of arc start can be commonly solved under the solution conditions of one welding machine, and efficient operation can be performed.

[0067]

As is apparent from the above description, according to the present invention, a high voltage suitable for the wire to be used is applied by switching and applying the high voltage adapted to the diameter of the indicating wire, so that a good arc start can be achieved. It is possible to improve the success rate of arc start.

Further, by switching and applying the high voltage corresponding to the arc break at the time of arc start, the high voltage corresponding to the arc state is applied, so that good arc start can be performed and the success rate of arc start can be improved. Can be improved.

Furthermore, by centrally controlling a plurality of welding machines so that the high voltage is applied by switching to a high voltage corresponding to the arc break at the time of each arc start, the high voltage corresponding to the arc state of each welding machine can be obtained. Since they are applied, each can have a good arc start, the success rate of each arc start can be improved, and if the welding conditions of each welder are the same, unspecified 1
Appropriate conditions of the table can be reflected to other welding machines, good arc start can be performed from the first time, problems such as arc break can be prevented, and efficient operation can be performed.

Further, a high voltage adapted to the indicated welding current is
By switching and applying according to the arc break at the time of arc start, a high voltage adapted to the welding current is applied first, and then it is switched and applied according to the arc state, so a better arc start can be achieved. , The success rate of arc start can be improved.

Further, for a plurality of welding machines, the high voltage adapted to the respective welding currents is centrally controlled so as to be switched and applied corresponding to the arc break at the start of the arc, so that the respective instructions are given first. A high voltage adapted to the welding current is applied, and switching is performed according to the arc state, so each can perform a good arc start and improve the success rate of arc start, and the welding conditions of each welder are the same. If unspecified 1
Appropriate conditions of the table can be reflected to other welding machines, good arc start can be performed from the first time, problems such as arc break can be prevented, and efficient operation can be performed.

Further, by applying a high voltage at the start of welding and at the end of welding, good restart on the crater can be performed and the success rate of arc start can be improved.

Also, by applying a high voltage adapted to the wire diameter at the start of welding and at the end of welding, good restart on the crater can be achieved depending on the wire diameter, and the success rate of arc start can be further improved. It can be further improved.

Further, by switching and applying a high voltage at the start of welding in response to an arc break, and by applying the high voltage at the end of welding as well, a good arc start can be performed and a very good re-creation on the crater can be achieved. I can start
The success rate of arc start can be improved.

Further, for a plurality of welding machines, high voltage is applied by switching to a high voltage corresponding to each arc break at the start of welding, and these high voltages are centrally controlled to be applied at the end of welding. Good arc start and restart on the crater, and if the welding conditions of each welder are the same, the appropriate condition of one unspecified can be reflected to other welders. Good arc start and restart can be performed, problems such as arc breaks can be prevented, and efficient operation can be performed.

Further, by switching and outputting the high voltage at the start of welding in accordance with the arc break state with respect to the predetermined voltage value adapted to the indicated welding current, and outputting the high voltage adapted to restart at the end of welding. In addition to a good arc start, a very good restart on the crater can be performed, and the success rate of arc start can be further improved.

Further, with respect to a plurality of welding machines, the high voltage at the start of welding is switched and output according to the arc break state with respect to the predetermined voltage adapted to the respective indicated welding current, and adapted to restart at the end of welding. By performing centralized control to output a high voltage, each can perform good arc start and restart, and when the welding conditions of each welder are the same, one unspecified appropriate condition can be used for other welders. Therefore, it is possible to perform a good arc start and restart for the first time, prevent problems such as arc breakage, and operate efficiently.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a third exemplary embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of a fourth exemplary embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a fifth exemplary embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of a sixth exemplary embodiment of the present invention.

FIG. 7 is a block diagram showing a configuration of a seventh embodiment of the present invention.

FIG. 8 is a block diagram showing a configuration of an eighth embodiment of the present invention.

FIG. 9 is a block diagram showing a configuration of a ninth embodiment of the present invention.

FIG. 10 is a block diagram showing the configuration of a tenth embodiment of the present invention.

FIG. 11 is a block diagram showing the configuration of an eleventh embodiment of the present invention.

FIG. 12 is a block diagram showing a system configuration for improving arc start performance in a conventional consumable electrode type arc welder.

[Explanation of symbols]

1 wire 2 wire feeding motor 3 electrode 4 base material 5 welding power source 6 high voltage generator 7 current detector 8 welding current indicator (welding current indicating means) 9 wire diameter input device (wire diameter input means) 10 switchable height Voltage generator (switching type high voltage generating means) 11 Arc breakage monitor (arc breakage monitoring means) 12 Monitoring type controller (monitoring type control means) 13 Multiple monitoring type controller (multiple monitoring type control means) 14 Current-monitoring Type controller (current-monitoring type control means) 15 multiple current-monitoring type controller (multiple current-monitoring type control means) 16 double-application high voltage generator (double-application high voltage generation means) 17 switchable type Double application type high voltage generator (switching type double application type high voltage generating means) 18 Switching type double application notification type high voltage generator (switching type double application type) Intelligent high voltage generating means) 19 Double applied current-monitoring controller (double applied current-monitoring control means) 20 Plural double applied current-monitoring controller (plural double applied current-monitoring control means)

─────────────────────────────────────────────────── --- Continuation of the front page (56) Reference JP-A-57-56167 (JP, A) JP-A-56-139285 (JP, A) JP-A-57-31475 (JP, A) JP-A-58- 90377 (JP, A) JP-B-45-38895 (JP, B1) (58) Fields investigated (Int.Cl. ⁷ , DB name) B23K 9/067 B23K 9/09 B23K 9/095 B23K 9/173 H02M 9/00

Claims (11)

(57) [Claims] 1. A wire diameter input means for indicating and inputting a wire diameter, and a switching type high voltage generating means for generating a high voltage whose voltage value can be switched in response to a welding start signal. the voltage value of the high voltage the is switchable high voltage generating means for generating, by a value adapted to the wire diameter
A high-voltage generating system, which is set by switching to a value at which the insulating material at the tip of the wire is destroyed . 2. An arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, a switching type high voltage generating means for generating a high voltage whose voltage value can be switched in response to a welding start signal, and the switching type. And a monitoring type control means for controlling the high voltage generating means, wherein the monitoring type control means sets the voltage value of the high voltage generated by the switching type high voltage generating means to a predetermined value, and then turns off the arc. A high voltage generation system that can be switched and set accordingly. 3. A plurality of weldings, arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, and switching type high voltage generation means for generating a high voltage whose voltage value can be switched in response to a welding start signal. Each machine has
A plurality of monitoring type control means for centrally controlling the voltage value of each of the switching type high voltage generating means are provided, and the plurality of monitoring type control means generate the respective switching type high voltage generating means for each of the welding machines that start an arc. A high voltage value is set to a predetermined value and then centrally controlled so as to be switched and set according to the arc breakage state, and when the welding conditions of the respective welding machines are the same, a plurality of weldings are performed. A high voltage generation system that controls by applying the switching setting of the unspecified welder of the machine to the rest of the other welders. 4. A welding current indicating means for indicating and inputting a welding current value, an arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, and a high voltage whose voltage value can be switched in response to a welding start signal. The switching-type high-voltage generating means and the current-monitoring type control means for controlling the switching-type high-voltage generating means are provided, and the current-monitoring-type control means has a high voltage generated by the switching-type high-voltage generating means. A high voltage generation system, wherein a voltage value of a voltage is set to a predetermined value adapted to the indicated current value, and then switched and set according to the arc cut state. 5. A welding current indicating means for indicating and inputting a welding current value, an arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, and a switchable high voltage generator for generating a high voltage whose voltage value can be switched. With a plurality of welding machines each having means, a plurality of current-monitoring type control means for centrally controlling each of the high-voltage generating means, the plurality of current-monitoring type control means, for each welding machine to start arc, The voltage value of the high voltage generated by the switching type high voltage generating means in response to the welding start signal is set to a predetermined value adapted to each of the indicated welding current values, and then switching setting is performed in correspondence with the arc cut state. Centralized control so that when the welding conditions of the welding machine are the same, switching of unspecified welding machines of a plurality of welding machines is performed. A high voltage generation system that applies settings to the rest of the welders to control them. 6. The tip of the wire is responsive to a welding start signal .
High voltage generates high voltage generating system having a double applied high-voltage generating means for generating a high voltage to again break the insulating material on crater in response to welding end signal to destroy the insulating material. 7. A wire diameter input means for indicating and inputting a wire diameter and a tip of the wire as a high voltage whose voltage value can be switched.
A high voltage to destroy the insulating material of the end the welding start signal, Kure
The high voltage that destroys the insulating material on the data is used as the welding end signal ,
Switch type double application type high voltage generating means generated in response to each , the wire diameter input means, the voltage value of the high voltage generated by the switch type double application type high voltage generating means,
A high-voltage generation system configured to be switched and set to a value adapted to the wire diameter. 8. An arc breakage monitoring means for monitoring a state of arc breakage at the time of arc start, and a switching type double application type for generating a high voltage whose voltage value can be switched in response to a welding start signal and a welding end signal. A high voltage generating means and a monitoring type control means for controlling the switching type double application type high voltage generating means are provided, wherein the monitoring type control means has a high voltage generated by the switching type double application type high voltage generating means. A high voltage generation system in which the voltage value of the voltage is switched and set according to the state of arc breakage with respect to a predetermined set voltage value. 9. An arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, and a switching type double application type for generating a high voltage whose voltage value can be switched in response to a welding start signal and a welding end signal. A plurality of welding machines are respectively provided with a high voltage generating means, and a plurality of monitoring type control means for centrally controlling the switching type double application type high voltage generating means are provided, and the plurality of monitoring type control means perform arc start. For each of the welding machines, the voltage value of the high voltage generated by the switching type double application type high voltage generating means is centrally controlled so as to be switched and set according to the arc cut state with respect to a predetermined set voltage value, and the welding is performed. If the welding conditions of the welding machines are the same as each other, the switching setting of the unspecified welding machine among the welding machines should be applied to the rest of the welding machines for control. High voltage generation system. 10. A welding current instructing means for instructing and inputting a welding current value, an arc breakage monitoring means for monitoring an arc breakage state at the time of arc start, and a high voltage whose voltage value is switchable are a welding start signal and a welding end signal. Switching type double application notification type high voltage generating means, which is generated in response to, and double applied current controlling the switching type double application notification type high voltage generating means-
Monitoring control means, wherein the double applied current-monitoring control means indicates the voltage value of the high voltage generated by the switching type double application notification type high voltage generation means in response to a welding start signal, by the instruction welding. After setting to a predetermined set voltage value corresponding to the current value, switching setting is performed corresponding to the arc cut state, and the high voltage voltage value generated in response to the welding end signal is switched to the voltage value suitable for restart. High voltage generation system designed to do. 11. An arc breakage monitoring means for monitoring a state of arc breakage at the time of arc start, and a switching type double application notification generated in response to a welding start signal and a welding end signal of a high voltage whose voltage value can be switched. Type high voltage generating means is provided in each of the plurality of welding machines, and a plurality of double applied current-monitoring control means for centrally controlling the switching type double application notification type high voltage generating means are provided. heavy applied current - monitoring control means, the welding machine individually for arc start, the voltage value of the high voltage the switching type dual application notification type high voltage generating means for generating in response to the welding start signal, the indication Switching setting is performed according to the arc break condition for a predetermined set voltage value adapted to the current value, and the high voltage value generated in response to the welding end signal is cut to the voltage value adapted to restart. If the welding conditions of the welder are the same, the switching setting of the unspecified welder of the plurality of welders is applied to the remaining other welders. High voltage generation system to control.