Method for plasma-cutting a workpiece by means of a plasma-cutting system and pulsating current

Abstract

A method for plasma cutting a workpiece comprises providing a plasma cutting system having a plasma current source and a plasma torch, the plasma torch having an electrode and nozzle where the nozzle is a small distance from the electrode at a lower end of the plasma torch, forming a plasma chamber between the nozzle and the electrode. A current is produced with a plasma current source and the current flows through the plasma torch during the plasma cutting process. The current is then brought to pulsation during at least a partial time period during the plasma cutting process, with the pulsation occurring in a targeted or controlled manner with a freely selectable frequency.

Claims

1. A method for plasma cutting a workpiece by means of a plasma cutting system, which comprises a plasma current source and a plasma torch, which comprises an electrode and a nozzle, having a gap to form a plasma chamber therebetween, the method comprising: sending to the plasma torch, from a gas console, both a plasma gas and a secondary gas, the secondary gas being fed to a plasma jet through a secondary gas guide; producing a cutting current by the plasma current source through the plasma torch and raising said cutting current in a targeted or controlled manner to a target arithmetic mean specified for plasma cutting; maintaining the cutting current at the target arithmetic mean for at least one second; and creating a pulsating cutting current I.sub.S by fluctuating said cutting current after maintaining the pulsating cutting current, at an arbitrary frequency f in a range of 0.1 Hz to 500 Hz.

2. The method for plasma cutting a workpiece of claim 1 wherein the arbitrary frequency f is in the range of from about 35 Hz to 500 Hz.

3. The method for plasma cutting a workpiece of claim 1 wherein the arbitrary frequency f is in the range of from about 55 Hz to 400 Hz.

4. The method for plasma cutting a workpiece of claim 1 wherein the pulsating cutting current I.sub.S fluctuates around an arithmetic average I.sub.m with at least one freely selectable peak value I.sub.min or I.sub.max in the range of from about 5% to 70% around the arithmetic average I.sub.m.

5. The method for plasma cutting a workpiece of claim 1 wherein the pulsating cutting current I.sub.S fluctuates around an arithmetic average I.sub.m with at least one freely selectable peak value I.sub.min or I.sub.max in the range of from about 10% to 50% around the arithmetic average I.sub.m.

6. The method for plasma cutting a workpiece of claim 1 wherein a minimum deviation of a peak value I.sub.max or I.sub.min from an arithmetic average value I.sub.m of the pulsating cutting current I.sub.s is 5 A.

7. The method for plasma cutting a workpiece of claim 1 wherein a minimum deviation of a peak value I.sub.max or I.sub.min from an arithmetic average value I.sub.m of the pulsating cutting current I.sub.s is 10 A.

8. The method for plasma cutting a workpiece of claim 1 wherein a minimum deviation of a peak value I.sub.max or I.sub.min from an arithmetic average value I.sub.m of the pulsating cutting current I.sub.s is 20 A.

9. The method for plasma cutting a workpiece of claim 1 wherein the maximum deviation of a peak value I.sub.max or I.sub.min from an arithmetic average value I.sub.m of the pulsating cutting current I.sub.s is 200 A.

10. The method for plasma cutting a workpiece of claim 1 wherein the maximum deviation of a peak value I.sub.max or I.sub.min from an arithmetic average value I.sub.m of the pulsating cutting current I.sub.s is 100 A.

11. The method for plasma cutting a workpiece of claim 1 wherein the amount of the maximum current change speed dI/dt of the pulsating cutting current I.sub.s is 400 A/ms.

12. The method for plasma cutting a workpiece of claim 1 wherein the amount of the minimum current change speed dI/dt of the pulsating cutting current I.sub.s is 2 A/ms.

13. The method for plasma cutting a workpiece of claim 1 wherein the scanning ratio D=t.sub.Imax/T of the pulsating cutting current I.sub.s lies between about 0.1 and 0.9.

14. The method for plasma cutting a workpiece of claim 1 wherein the scanning ratio D=t.sub.Imax/T of the pulsating cutting current I.sub.s lies between about 0.3 and 0.7.

15. The method for plasma cutting a workpiece of claim 1 wherein the freely selectable frequency f is in the range of from about 0.1 Hz to 29 Hz.

16. The method for plasma cutting a workpiece of claim 1 wherein the freely selectable frequency f is in the range of from about 0.1 Hz to 20 Hz.

17. The method for plasma cutting a workpiece of claim 1 wherein each cutting current pulse of the pulsating cutting current I.sub.s has a low threshold duration t.sub.Imin and a high threshold duration t.sub.max such that:
t.sub.Imin+t.sub.Imax=T; where period duration T=1/f; and t.sub.Imin or t.sub.Imax<25% of the period duration T.

18. The method for plasma cutting a workpiece of claim 1 wherein each cutting current pulse of the pulsating cutting current I.sub.s has a low threshold duration t.sub.Imin and a high threshold duration t.sub.Imax such that:
t.sub.Imin+t.sub.Imax=T; where period duration T=1/f; and t.sub.Imin or t.sub.Imax<15% of the period duration T.

19. The method for plasma cutting a workpiece of claim 1 wherein each cutting current pulse of the pulsating cutting current I.sub.s has a low threshold duration t.sub.Imin and a high threshold duration t.sub.Imax such that:
t.sub.Imin+t.sub.Imax=T; where period duration T=1/f; and t.sub.Imin or t.sub.Imax<50% of the period duration T.

20. The method for plasma cutting a workpiece of claim 1 wherein each cutting current pulse of the pulsating cutting current I.sub.s has a low threshold duration t.sub.Imin and a high threshold duration t.sub.Imax such that:
t.sub.Imin+t.sub.Imax=T; where period duration T=1/f; and t.sub.Imin or t.sub.Imax<30% of the period duration T.

21. The method for plasma cutting a workpiece of claim 1 wherein a cutting voltage comprises an arithmetic average value in the range of from about 90 V to 250 V.

22. The method for plasma cutting a workpiece of claim 1 wherein a cutting voltage comprises an arithmetic average value in the range of from about 120 V to 220 V.

23. The method for plasma cutting a workpiece of claim 1 wherein plasma gas volume flow is kept constant.

24. The method for plasma cutting a workpiece of claim 1 wherein the electrode is a flat electrode.

25. The method for plasma cutting a workpiece of claim 1 wherein plasma gas is brought into rotation in the plasma chamber.

26. The method for plasma cutting a workpiece of claim 1 wherein an oxygen-containing plasma gas is used.

27. The method for plasma cutting a workpiece of claim 1 wherein the arithmetic average of the cutting current I.sub.s has a value in the range of from about 25 A to 500 A.

28. The method for plasma cutting a workpiece of claim 1 further comprising: Providing a direct current cutting current; and Creating the conditions for the direct current cutting current to meet the target range by either superimposing an alternating current or fluctuating the direct current cutting current.

29. The method for plasma cutting a workpiece of claim 1 wherein the secondary gas is set in rotation through the secondary gas guide through bores and fed to the plasma jet.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages of the invention ensue from the following description, in which several embodiments of the present invention are described by reference to the drawings, in which:

(2) FIG. 1 depicts a schematic diagram of a plasma cutting system according to the prior art;

(3) FIG. 2 graphically depicts the course of a plasma cutting process according to the prior art, shown schematically;

(4) FIG. 3 graphically depicts the course of a plasma cutting process according to a particular embodiment of the present invention, shown schematically;

(5) FIGS. 4 through 9 graphically depict particular embodiments of the plasma cutting process according to a first aspect of the present invention:

(6) FIGS. 10 through 18 graphically depict particular embodiments of the plasma cutting process according to a second aspect of the present invention;

(7) FIG. 19 depicts a side cross sectional view of a plasma torch with a flat electrode; and

(8) FIG. 19a depicts the plasma torch of FIG. 19 additionally with rotation of plasma gas and secondary gas.

DETAILED DESCRIPTION

(9) FIG. 1 depicts a schematic diagram of a plasma cutting system that includes a plasma current source 1, the components of which are a current source 1.1, an ignition unit 1.2, a resistor 1.3, and a contact 1.4. The negative pole of the current source is connected with the line 10.5 to the electrode 4.1 of the plasma torch 4 and the positive pole with the line 10.7 to the workpiece 5, and via the resistor 1.3, the ignition unit 1.2, and the contact 1.4 via the line 10.6 to the nozzle 4.2 of the plasma torch 4. The plasma current source is generally supplied by a three-phase current network, e.g. 400 V 50 Hz, with electrical energy. The gas supply of the plasma torch takes place via the gas console 2, in which there can be valves, e.g. magnetic valves and/or regulating valves (not shown) to switch the gases, in particular the plasma gas (PG) and the secondary gas SG. The gas supply takes place through gas bottles 2.1 for the plasma gas and 2.2. for the secondary gas. In case of cutting non-alloyed or low-alloy steels, oxygen is often used as a plasma gas but an oxygen-containing gas, e.g. air or gas mixture, e.g. nitrogen/oxygen, can also be used. By way of a secondary gas, oxygen can also be used. An oxygen-containing gas, e.g. air or gas mixture, e.g. nitrogen/oxygen or nitrogen can also be used. The plasma gas PG is conveyed via the gas line 10.3 into the space between the electrode 4.1 and nozzle 4.2, the plasma chamber, and the secondary gas SG is conveyed via the gas line 10.4 into the space between the nozzle 4.2 or nozzle cap 4.4 (not shown) and the nozzle protection cap 4.5.

(10) Comparing FIG. 1 to FIG. 2, the sequence during plasma cutting according to the prior art is described below. Initially the plasma torch 4 is positioned with the aid of a guide system, for example a CNC-controlled xy coordinate guide machine or a robot at a defined distance from the workpiece 5. The signal sent by the guide system to the plasma current source “torch ON” starts the process. Plasma gas PG and secondary gas SG, controlled by the gas console, then flow through the plasma torch 4. After an amount of time, for example 400 ms, the ignition unit 1.2 ignites with high voltage the pilot arc which burns between the electrode 4.1 and the nozzle 4.2 and ionises the section between the plasma torch 4 and the workpiece 5. The pilot current I.sub.pilot is limited by the resistor 1.3. Typical values for the pilot current are 12 to 35 A. The resistor 1.3 simultaneously produces a voltage drop between the nozzle 4.2 and the workpiece 5, which supports the transition of the anodic attachment point from the nozzle to the workpiece. After the transition of the current I the contact 1.4 is opened, the current I is increased during the time t.sub.up (range from 50 ms to 500 ms) to the required cutting value. The cutting current I.sub.s forms which flows during the time t.sub.s. The values for the cutting current I.sub.s lie, according to the panel thickness to be cut, which can usually be between 1 and 200 mm, between 20 and 1000 A. The current flowing during this time should be as even as possible. The current I flows until the signal “torch ON” is switched off and then the current I is reduced during the time t.sub.down and switched off. Usual values for this time are 50 to 500 ms but the current can also be switched off immediately without this time. Plasma gas and secondary gas continue to flow in order to further cool the plasma torch. It is also possible to work with different plasma and secondary gases and also different pressures and gas quantities in the process phases.

(11) Referring now to FIG. 3, in contrast with the prior art, a cutting current I.sub.s fluctuates in a defined manner, shown merely by way of example, during the time t.sub.s according to a particular embodiment of the invention. In order to carry out the plasma cutting method according to a particular embodiment of the invention, the plasma cutting system of FIG. 1 can also be used.

(12) FIGS. 4 through 9 graphically depict embodiments for cutting current patterns according to the present invention, whereby FIG. 4 relates to the cutting current pattern indicated in FIG. 3.

(13) FIG. 4 graphically depicts a cutout of the current I.sub.s flowing during the time t.sub.s. The arithmetic average I.sub.m of the current amounts to 160 A, the maximum current I.sub.max is 180 A, and the minimum current I.sub.min is 140 A. The deviation of the values I.sub.max and I.sub.min from the arithmetic average value I.sub.m is of equal magnitude and amounts to 20 A and thus 12.5%. The alternating current superimposed in relation to the direct current is formed trapezoidally.

(14) The current change speeds dI/dt, i.e. the amounts of the current changes in a time which is necessary in order to pass from: the arithmetic average I.sub.m to the maximum cutting current I.sub.max
dI/dt.sub.1=|(I.sub.max−I.sub.m)|/t.sub.1 the maximum cutting current I.sub.max to the arithmetic average I.sub.m
dI/dt.sub.2=|(I.sub.m−I.sub.m)|/t.sub.2 the arithmetic average value I.sub.m to the minimum cutting current I.sub.min
dI/dt.sub.3=|(I.sub.max−I.sub.m)|/t.sub.3 the minimum cutting current I.sub.min to the arithmetic average I.sub.m
dI/dt4=|(I.sub.max−I.sub.m)|/t.sub.4,
are constant, as the amounts of the differences between the maximum cutting current and the arithmetic average of the cutting current and the minimum cutting current and the arithmetic average of the cutting current are respectively 20 A and the respective times t1, t2, t3, t4 are of equal magnitude and respectively 0.5 ms, amounting to 40 A/ms.
dI/dt.sub.1=(I.sub.max−I.sub.m)/t.sub.1=(180 A−160 A)/0.5 ms=40 A/ms

(15) The period duration T amounts to 12 ms and the frequency f thus 83 Hz. More than a doubling of the lifespan was achieved with this current pattern (see above example of the plasma cutting of 15 mm structural steel).

(16) FIG. 5 graphically depicts a triangular current pattern, wherein the period duration, frequency, minimum and maximum cutting current and the arithmetic average of the cutting current are identical to FIG. 4. The current change speeds, being 6.6 A/ms, are lower and of equal magnitude.

(17) FIG. 6 graphically depicts a sinusoidal current pattern with a period duration of 6 ms and a frequency of 166 Hz. The arithmetic average I.sub.m of the current amounts to 300 A, the maximum current I.sub.max is 350 A, and the minimum current I.sub.min is 250 A. The deviation of the values I.sub.max and I.sub.min from the arithmetic average I.sub.m is of equal magnitude and amounts to 50 A and thus 16%. The current change speeds amount to 33 A/ms and are of equal magnitude.

(18) FIG. 7 graphically depicts a current pattern which is similar to an e-function. The period duration amounts to 4 ms and the frequency 250 Hz. The arithmetic average value I.sub.m of the current amounts to 300 A, the maximum current I.sub.max is 400 A and the minimum current I.sub.min is 200 A. The deviation of the values I.sub.max and I.sub.min from the arithmetic value I.sub.m is of equal magnitude and amounts to 100 A and thus 33%. The current change speeds in this example are different and have the following values:
dI/dt.sub.1=dI/dt.sub.3=100 A/1.7 ms=59 A/ms
dI/dt.sub.2=dI/dt.sub.4=100 A/0.3 ms=333 A/ms

(19) FIG. 8 graphically depicts a trapezoidal current pattern, whereby this time the differences between the maximum cutting current I.sub.max and the arithmetic average I.sub.m of the cutting current I.sub.s and between the minimum cutting current I.sub.min and the arithmetic average value I.sub.m of the cutting current I.sub.s and the times t.sub.Imax (2 ms) and t.sub.Imin (4 ms) are different:
|Imax−Im|=|260 A−160 A|=100 A
|Imin−Im|=|110 A−160 A|=50 A

(20) The period duration T amounts to 6 ms and the frequency 166 Hz. The current change speeds are of equal magnitude in this example and amount to 200 A/ms.
dI/dt.sub.1=dI/dt.sub.2=100 A/0.5 ms=200 A/ms
dI/dt.sub.3=dI/dt.sub.4=50 A/0.25 ms=200 A/ms

(21) FIG. 9 also graphically depicts a trapezoidal current pattern, wherein the differences between the maximum cutting current I.sub.max and the arithmetic average I.sub.m of the cutting current I.sub.s and between the minimum cutting current and the arithmetic average I.sub.m of the cutting current I.sub.s and the times t.sub.Imax (2 ms) and t.sub.Imin (3 ms) are different and the cutting current is a time in relation to its arithmetic average value I.sub.m:
|Imax−Im|=|235 A−160 A|=75 A
|Imin−Im|=|110 A−160 A|=50 A

(22) The period duration T amounts to 6 ms and the frequency 166 Hz. The current change speeds are of equal magnitude in this example and amount to approximately 200 A/ms.
dI/dt.sub.1=dI/dt.sub.2=100 A/0.37 ms=200 A/ms
dI/dt.sub.3=dI/dt.sub.4=50 A/0.25 ms=200 A/ms

(23) FIGS. 10 to 13 graphically depict particular embodiments of the plasma cutting method according to the second aspect of the present invention. Instead of a superimposition of a direct current with an alternating current the cutting current can be described in these cases as a periodically repeating pulse sequence. In FIGS. 10 and 11 the signal form with the period duration (T (=1/f) contains a rectangular pulse downwards (FIG. 10) or a rectangular pulse upwards (FIG. 11), starting from a base value. In FIGS. 12 and 13, in comparison, the signal form comprises both a rectangular impulse upwards and downwards, whereby the signal forms in FIGS. 12 and 13 differ merely in the time distance between the rectangular pulses upwards and downwards.

(24) FIG. 14 graphically depicts a concrete numerical example for the embodiment according to FIG. 10, while in FIG. 15 a concrete embodiment for the embodiment form according to FIG. 11 is shown. In both cases the following applies for the sum of t.sub.Imax (the high threshold duration), and of t.sub.Imin (the low threshold duration), and the period T:
t.sub.Imin+t.sub.Imax=T,
whereby T is 500 ms, t.sub.Imax 470 ms and t.sub.Imin 30 ms. For I.sub.max (high threshold)=300 A and I.sub.min (low threshold)=220 A there is an arithmetic average I.sub.m of the cutting current at the level of 295 A.

(25) In an example graphically depicted in FIG. 15, the period duration T (=1/f) is also 500 ms, but t.sub.Imax is 30 ms and t.sub.Imin 470 ms. When I.sub.max=400 A and I.sub.min=300 A, there is an arithmetic average I.sub.m of the cutting current I.sub.s of 306 A.

(26) FIGS. 16 and 17 graphically depict examples in which the following applies for the pulses of the cutting current I.sub.s:
t.sub.Imin+t.sub.Imax<T

(27) FIG. 16 graphically depicts a numerical example for the embodiment according to FIG. 13, while FIG. 17 graphically depicts a numerical example for the embodiment according to FIG. 14. In FIG. 16 the period duration T is 500 ms, while both t.sub.Imax and t.sub.Imin are clearly smaller, namely being respectively 25 ms. For I.sub.max=400 A and I.sub.min=200 A, there is thus an arithmetic average value I.sub.m of the cutting current I.sub.s of 300 A.

(28) In FIG. 17 the period duration T is 650 ms and t.sub.Imax and t.sub.Imin are clearly lower, namely respectively 50 ms. With a maximum current I.sub.max of 450 A and a minimum current of I.sub.min of 250 A, there is thus an arithmetic average value I.sub.m of 350 A.

(29) In the signal pattern graphically depicted in FIG. 18 of the cutting current I.sub.s there is in turn a pulse sequence with a period duration T (=400 ms)=t.sub.Imin+t.sub.Imax, wherein t.sub.Imax is 300 ms and t.sub.Imin is 100 ms. The periodic signal form does not have, however, a rectangular pulse but instead a tooth-like or barb-like progression. t.sub.Imin corresponds to the time during which the cutting current I.sub.s deviates from I.sub.max (=300 A). In case of a minimum current of I.sub.min, of 200 A, there is thus an arithmetic average value I.sub.m of the cutting current I.sub.s of 290 A.

(30) Finally FIG. 19 depicts a cross sectional side view of a plasma torch 4 with a flat electrode 4.2, that can be advantageously used with the invention.

(31) The depicted components of the plasma torch 4 (of which only a plasma torch head is shown) are an electrode 4.1 in the form of a flat electrode, which includes an electrode holder 4.1.1 and an emission insert 4.1.2, a nozzle 4.2 with a nozzle bore 4.2.1, wherein the nozzle 4.2 and the electrode 4.1 form between them a plasma chamber 4.7. A plasma gas PG is conveyed into the plasma chamber 4.7 by a plasma gas guide 4.3 which sets the plasma gas in rotation through appropriately arranged bores, and in the plasma chamber 4.7 it is ionised by a plasma arc and a plasma jet 6 (not shown, but see FIG. 1) is formed. The nozzle 4.2 is fixed by a nozzle cap 4.4. In the area enclosed by both, a coolant flows from a coolant supply WV2 to a coolant return WR2 and cools the nozzle 4.2 and the nozzle cap 4.4. The electrode 4.1 formed hollow inside, into which a cooling pipe 4.8 projects, is also cooled by a coolant. The coolant flows from a coolant supply WV1 through the cooling pipe 4.8 into the hollow chamber of the electrode 4.1 to the electrode tip and then between the cooling pipe 4.8 and the electrode 4.1 to a coolant return WR1. Distilled water, which can be provided with a frost protection additive, is used in this example as a coolant. A water cooling circuit (not shown) is advantageous for cooling the coolant by means of a heat exchanger (not shown) or a refrigerating machine (not shown) and feeds the coolant via a pump (not shown) back to the plasma torch. The volume flow and temperature of the coolant can thereby be monitored and/or controlled.

(32) The secondary gas SG flows into a chamber between the nozzle cap 4.4 and a nozzle protection cap 4.5 and is set in rotation through a secondary gas guide 4.6 through appropriate bores and then fed to the plasma jet 6. The secondary gas SG protects, in combination with the nozzle protection cap 4.5, in particular the nozzle 4.2, and the nozzle cap 4.4 upon penetration into a workpiece 5 (see FIG. 1) against damage from spattering material.

(33) FIG. 19a additionally depicts, schematically, the rotation of the plasma gas PG and the secondary gas SG produced by the respective gas guide.

(34) Further aspects of the current invention also include: that the current I fluctuates periodically, i.e. with constant frequency f; that the frequency of the cutting voltage is independent and/or kept constant; that the current I fluctuates around its arithmetic average during the whole process (pilot, transfer (t.sub.up), cutting (t.sub.s), current reduction at the end of cutting (t.sub.down); that the current fluctuates around its arithmetic average during cutting (t.sub.s), transfer (t.sub.up) and/or current reduction (t.sub.down); that the current I fluctuates around its arithmetic average only after reaching said arithmetic average predefined for cutting; that the current I fluctuates around its arithmetic average only at least 1 second after reaching said arithmetic average value predefined for cutting; that the average current density of the area of the nozzle bore 4.2.1 is between about 30 and 150 A/mm.sup.2; that the average current density of the area of the nozzle bore 4.2.1 is between about 60 and 150 A/mm.sup.2; that the plasma gas PG is set in rotation through a gas guide in the space between the electrode 4.1 and the nozzle 4.2; that the volume flow of the plasma gas PG lies in the range of from about 700 l/h to 7000 l/h; that the pressure of the plasma gas PG in the space between the electrode 4.1 and the nozzle 4.2 lies between about 2.5 and 8 bar; that the plasma gas PG is oxygen, an oxygen-containing gas or gas mixture; that the plasma gas PG comprises at least a molecular gas such as oxygen, nitrogen, and/or hydrogen; that the plasma gas PG comprises at least at the rate of 30% by volume of a molecular gas such as oxygen, nitrogen, and/or hydrogen; that the plasma torch 4 has water cooling; that a database is provided, in which by way of cutting parameters of at least material, cutting current, cutting speed and plasma gas are defined; that an electrode 4.1 for a plasma torch is provided, wherein the electrode holder 4.1.1 is hollow inside and forms an inner surface; that the electrode 4.1 is formed as a flat electrode; that the electrode 4.1 is water cooled; that the emission insert 4.1.2 has a diameter of about 0.9 to 8 mm; that the nozzle bore 4.2.1. has a diameter of about 0.4 to 7 mm; that the nozzle 4.2 is water cooled; that a gas guide part is present in the space between the electrode 4.1 and the nozzle 4.2; that a nozzle protection cap 4.5 is present; that a gas guide ring is present between the nozzle protection cap 4.5 and the nozzle cap 4.4 or nozzle 4.2; that the gas guide ring sets the secondary gas SG in rotation.

(35) The features of the invention disclosed in the present description, in the drawings and in the claims can be essential both individually and also in any combination for the realisation of the invention in its different embodiments.