Control method for MIG/MAG-welding and welding equipment applying this method

The invention claimed is: 1. A control method for MIG/MAG-welding with presence of short-circuiting droplets between an electrode end and a workpiece, the method comprising: measuring a short-circuiting time duration; measuring an arc time duration; controlling energy supplied to the electrode by a process regulator by: calculating a period time duration by summing the arc time duration and the short-circuiting time duration, calculating a short-circuiting percentage as a ratio of the measured short circuiting time duration over the period time duration, determining whether the period time duration exceeds a threshold value, in response to determining that the period time duration exceeds the threshold value, decreasing the energy supplied regardless of the short-circuiting percentage, in response to determining that the period time duration does not exceed the threshold value: increasing the energy supplied in response to the short-circuiting percentage exceeding a defined adjustable set value, and decreasing the energy supplied in response to the short-circuiting percentage being less than the defined adjustable set value. 2. The control method according to claim 1 , wherein the control is performed in order to achieve the defined adjustable set value for the short-circuit time duration as a part of the period time duration. 3. The control method according to claim 1 , wherein the controlling the energy supplied to the electrode comprises determining the energy supplied based at least in part on an amplifying constant, wherein the amplifying constant is selected to obtain a continuance state after a disturbance within 50-1000 milliseconds. 4. The control method according to claim 1 , wherein the step of measuring the short-circuiting time duration comprises establishing a short-circuiting, which is based on a measured voltage and the short-circuiting is considered to be present when the voltage goes below an established limit value for the short-circuiting. 5. The control method according to claim 1 , wherein the step of measuring the arc time duration comprises establishing an arc, which is based on a measured voltage and the arc is considered to be present when measured voltage exceeds an established value for the arc. 6. The control method according to claim 1 , wherein the step of measuring the short-circuiting time duration comprises establishing a short-circuiting, which is based on light measurement and a short-circuiting is considered to be present when a light intensity goes below an established limit value for short-circuiting, and arc is considered to be present when a measured light intensity exceeds an established value for the arc. 7. The control method according to claim 1 , wherein the step of measuring the arc time duration comprises establishing an arc, which is based on light measurement and an arc is considered to be present when a measured light intensity exceeds an established value for the arc. 8. The control method according to claim 1 , wherein the step of measuring the short-circuiting time duration comprises establishing a short-circuiting, which is based on sound measurement and a short circuit is considered to be present when a measured sound frequency has a predetermined value. 9. The control method according to claim 1 , wherein the step of measuring the arc time duration comprises establishing an arc, which is based on sound measurement and an arc is considered to be present when a measured sound frequency has a predetermined value. 10. Welding equipment for MIG/MAG welding, comprising: a weld torch holding an electrode having an electrode end adapted to be fed to a position in proximity to a workpiece; a welding machine adapted to supply energy to the electrode; a regulator including software and hardware components operable for causing the regulator to: measure a short-circuiting time duration based on an occurrence of a short circuit between the electrode and the workpiece; measure an arc time duration based on an occurrence of an arc between the electrode and the workpiece; and sum the arc time duration and the short-circuiting time duration to form a period time duration; and a process regulator adapted to control energy supplied to the electrode by: determining whether the period time duration exceeds a threshold value; in response to determining that the period time duration exceeds the threshold value, decreasing the energy supplied regardless of a short-circuiting percentage; in response to determining that the period time duration does not exceed the threshold value: increasing the energy supplied in response to the measured short-circuiting time duration, as a percentage of the period time duration, exceeding a defined adjustable set value, and decreasing the energy supplied in response to the short-circuiting percentage being less than the set value. 11. The welding equipment according to claim 10 , wherein the process regulator controls dynamic characteristics of the welding equipment. 12. The welding equipment according to claim 11 , where the process regulator receives an input signal from the regulator for maintaining the short-circuiting percentage constant. 13. The welding equipment according to claim 10 , wherein the regulator for maintaining the short-circuiting percentage constant controls an ignition angle for thyristors in a power module in the welding machine. 14. The welding equipment according to claim 10 , wherein the regulator for maintaining the short-circuiting percentage constant controls an electrode feeder so that more electrode is fed when the short-circuiting percentage goes below the defined set value and vice versa. 15. The welding equipment according to claim 10 , further comprising a memory for storing the latest used control parameters and applying the latest used control parameters at the next weld start. 16. A control method for MIG/MAG-welding with presence of short-circuiting droplets between an electrode end and a workpiece, the method comprising: measuring a short-circuiting time duration between the electrode end and the workpiece; measuring an arc time duration between the electrode end and the workpiece; calculating a period time duration by summing the arc time duration and the short-circuiting time duration; determining a short-circuit percentage as a ratio of the short-circuiting time duration over the period time duration; determining a difference between the short-circuit percentage and a set value; and generating an output signal to control energy supplied to the electrode based at least in part on the difference between the short-circuit percentage and the set value, by: determining whether the period time duration exceeds a threshold value; in response to determining that the period time duration exceeds the threshold value, decreasing the energy supplied regardless of the short-circuiting percentage; in response to determining that the period time duration does not exceed the threshold value: increasing the energy supplied in response to the determined short-circuit percentage exceeding the set value; and decreasing the energy supplied in response to the determined short-circuiting percentage being less than the set value. 17. The control method according to claim 16 , wherein the short-circuit time duration is a first measured short-circuit time, the arc time duration is a first measured arc time, the short-circuit percentage is a first short-circuit percentage, and the output signal is a first output signal, the method further comprising: