WO2023041419A2

WO2023041419A2 - Method for checking a laser machining process, and associated laser machine tool

Info

Publication number: WO2023041419A2
Application number: PCT/EP2022/075040
Authority: WO
Inventors: Tobias Kaiser; Martin Petera; Christoph Kraus
Original assignee: TRUMPF Werkzeugmaschinen SE + Co. KG
Priority date: 2021-09-14
Filing date: 2022-09-08
Publication date: 2023-03-23
Also published as: WO2023041419A3; DE102021123783A1

Abstract

The invention relates to a method for machining metal workpieces (2) by means of a laser beam (3) of a laser machine tool (1) with a laser beam power of at least 10 kW, wherein the laser machining is controlled by a tool controller (10) by means of at least one laser machining parameter, the parameter value of which can be manually entered. According to the invention, an input value manually entered for the at least one laser machining parameter is checked by the tool controller (10) as to whether damage to the laser machine tool (1) by the laser beam (3) is to be expected for laser machining using this input value. If no damage is to be expected, the input value is adopted by the tool controller (10) as a new parameter value of the laser machining parameter.

Description

Method for checking a laser processing procedure and associated laser processing machine

The invention relates to a method for processing, in particular cutting, metal, in particular plate-shaped workpieces using a laser beam from a laser processing machine with a laser beam power of at least 10 kW, the laser processing being controlled by a machine controller using at least one laser processing parameter, the parameter value of which can be entered manually, as well as a laser processing machine suitable for carrying out this process.

Such methods for laser processing are well known from the prior art.

With increasing laser power, the risk also increases that machine parts of the laser processing machine are unintentionally destroyed. The machine operator can have a significant influence on this by (in)appropriately selecting the cutting parameters. On the user interface of the laser processing system, the operator can change processing parameters in laser technology tables. So it is conceivable that out of ignorance or inadvertently, for example, the cutting speed is chosen so low that large parts of the laser radiation pass through the workpiece to be processed unused and melting of the machine base. Or the combination of laser beam (diameter, focus position) and nozzle diameter can lead to a collision and thus melting of the cutting nozzle. Especially with high laser powers > 10 kW, critical states can be reached quickly, which in the worst case can lead to the destruction of the machine and its radiation protection housing.

US 2004/0019403 A1 discloses a method for determining the compatibility of input parameters for use with a laser drilling system. The method includes providing compatibility data characteristic of a plurality of laser drilling operations and comparing the input parameters for a laser drilling operation to the compatibility data, thereby determining whether the input parameters are incompatible.

US 2020/0246920 A1 relates to a laser cutting device with a control unit in whose memory a large number of processing tables are stored. Each of the machining tables contains data on machining a workpiece, such as laser output power and cutting speed. The control unit selects a machining table such that given conditions for machining the material are satisfied, and controls cutting of the material based on the selected machining table.

WO 2019/145513 A2 discloses a method for determining processing parameters for processing a material using a laser processing system. The method includes providing a central processing unit with a machining learning function which, based on a plurality of previously used machining data, learns the selection of suitable machining parameters. The machining learning function enables the laser machining system to machine the material to be machined according to a desired machining result.

A programming system for creating machining programs for machine tools on the basis of data sets is known from EP 2 037 341 A2. A convention checking unit checks the data set to determine whether a contour of a material specified by the data set can be produced with the tool provided for producing the contour. If the check is successful, the data set is transferred to a program memory of the programming system.

In contrast, it is the object of the invention, in a laser processing method and a laser processing machine of the type mentioned at the outset, to reduce the risk of machine parts of the laser processing machine being unintentionally destroyed by the laser power.

This object is achieved according to the invention in the method mentioned at the outset in that an input value entered manually for at least one laser processing parameter is checked by the machine controller to determine whether damage to the laser processing machine by the laser beam is to be expected during laser processing with this input value, and that for the If no damage is to be expected, the input value is accepted by the machine control as the new parameter value of the laser processing parameter. If damage is to be expected, the input value cannot be accepted by the machine control, for example, or only with a warning, or can be corrected by the machine control to a damage-uncritical parameter value of the laser processing parameter, in particular to the nearest damage-uncritical parameter value. The input value can also be accepted unchanged by the machine control as the new parameter value of the laser processing parameter and the parameter value of at least one other laser processing parameter can be changed by the machine control such that both the input value of one laser processing parameter and the changed parameter value of the other laser processing parameter are not critical for damage.

According to the invention, operator inputs are checked by the machine control and, for example, if limit values are exceeded or not reached, the input values are noted as impermissible or corresponding adjustments are made on the machine side so that no critical states arise. A machine-side adjustment can, for example, adjust the speed of a scrap be conveyor belts. A warning message can also be issued for several limit values or for individual, possibly less critical, laser processing parameters. All processing parameters that can be changed by the machine operator and that affect the longevity of the machine should preferably be provided with at least one limit value on the machine control. This limit value can be an absolute value or a percentage change in the specified standard parameter. However, the limit value can also be calculated using the combination of at least two parameters.

Entered parameter values for laser technology tables, for example, are checked for meaningfulness, and a machine operator is given assistance when editing the processing technologies, so that parameter value inputs that could lead to damage to the machine components of a laser processing machine, including the laser processing head, are prevented. When calculating a possible impingement of a laser beam on the nozzle inner wall of a cutting nozzle in a laser processing head, the focus position, focus diameter and beam quality (SPP) of the laser beam and/or the position of the narrowest nozzle inside diameter in the beam direction must be taken into account as laser processing parameters. In this way, unintentional damage to the laser processing machine due to incorrect input can be avoided. Unnecessary energy consumption can also be avoided, for example if a cutting speed for a material is selected so low that large parts of the laser radiation radiate unused through the material. A substructure of the laser processing machine can be melted on. An incorrectly selected parameter value or an incorrectly selected parameter value combination for setting the laser beam, in particular with regard to its diameter and focus position, and a nozzle diameter of a processing nozzle in a laser processing head, from which the laser beam emerges, can lead to the processing nozzle being irradiated by the laser beam and thus to lead to melting of the processing nozzle. With high laser powers of more than 10 kW, critical states can quickly be reached which can lead to the destruction of the laser processing machine and its radiation protection housing. The at least one laser processing parameter is preferably one or more of the following laser processing parameters: focus position of the laser beam, focus diameter of the laser beam, feed rate of the laser beam when processing a workpiece and minimum speed of the laser beam when approaching a workpiece.

In a preferred variant of the method, an upper and/or a lower limit value of the at least one laser processing parameter for damage-free laser processing is defined in the machine control. If the input value of the at least one laser processing parameter is greater than the upper limit value or smaller than the lower limit value, the input value is not accepted by the machine control or only with a warning or is corrected by the machine control to a non-damage-critical parameter value, in particular to the nearest non-damage-critical parameter value. Based on limit values that are stored for the individual laser processing parameters, input values that can lead to damage to the machine should not be permitted. The input of parameter values by an operator on a user interface of the laser processing machine are checked using the limit values. The limit values represent specified values of the laser processing parameters, above and below which the laser processing machine is damaged by the laser radiation during the processing of the workpiece. The maximum thermal load on the machine base can be determined for various parameter values of laser processing parameters in test runs in order to determine the limit values for laser processing parameters. The upper and/or the lower limit value of the at least one laser processing parameter is advantageously defined as an absolute or percentage deviation from a standard value of the laser processing parameter.

In another preferred variant of the method, damage-critical value combinations of at least two laser processing parameters are defined in the machine control. The damage-critical value combinations represent, in particular, predetermined combinations of parameter values of laser processing parameters, in which the laser processing machine at the Workpiece processing is damaged by the laser radiation. The laser processing parameters can be, for example, the nozzle diameter of a processing nozzle and the focal position or the focal diameter and focal position.

If the input value of the at least one laser processing parameter together with the parameter value of the other laser processing parameter represents a critical value combination, the input value is not accepted or only with a warning or is corrected by the machine control to a non-damage critical parameter value, in particular to the nearest non-damage critical parameter value.

If the input value is not accepted because it is impermissible, it can be visualized as impermissible in an input display or deleted and, in particular, replaced by a permissible parameter value that comes closest to the impermissible value. If the input value is visualized with a warning, an operator has the option of correcting the parameter value while the process is running, in particular before or during a machining operation. A warning can be issued in particular for less critical laser processing parameters. Excessive deviations from a standard parameterization are preferably displayed in order to draw the operator's attention to possible processing problems that may result. In this case, the input values of the laser processing parameters are not prohibited, but only visualized by warnings.

Impermissible input values and warnings of impermissible or critical input values are preferably visualized immediately after they have been entered in an input terminal of the machine controller, also referred to as an HMI (Human Machine Interface). Impermissible changes, ie changes that lead to critical states in the laser processing machine, are preferably already recognized and displayed in the input terminal and particularly preferably not permitted. Preferably, different icons or markers are used for illegal input ("error") and for potentially critical input ("warning"). If you enter an invalid value, a Laser processing parameters, eg by changing the focus position, the cutting nozzle and/or the cutting speed, a symbol or a marking can appear in the respective input field and the input value can be overwritten with an original, permissible entry, preferably in the event of errors. Alternatively, an error message and a warning can be output as a text message "This input value is not permitted" or "This input value can lead to incorrect cuts or machine damage".

A minimum approach speed of a laser processing head for approaching a workpiece is preferably defined as the lower limit in the machine control system as a function of a laser power and/or a focus diameter of the laser beam from the laser processing head. The combination of laser power and focus diameter that is not critical to damage is preferably selected in such a way that this minimum approach speed is not fallen below when approaching a workpiece. For different laser powers, different minimum approach speeds of the laser processing head are stored in a laser technology table in the machine control. The minimum approach speed when starting is based on the speed value in the laser technology table. If an operator of the laser processing machine wants to change a speed value (in particular the feed speed) and/or the laser power and/or the focus diameter (manually) (e.g. in the case of the speed value using a potentiometer), the machine control checks and ensures that the minimum approach speed of the laser processing head is not fallen below and thus reaches a range of critical speed values. In particular, the machine control monitors its own, changed or imported laser technology tables and prevents laser processing using a laser technology table if the minimum approach speed is not reached. Alternatively or additionally, the laser power can be adjusted by the machine control to a predetermined minimum approach speed of the laser processing head. Similar to the minimum approach speed, minimum processing speeds (or minimum feed speeds) can also be defined during the processing of a workpiece as a function of the laser power and/or the focus diameter, and compliance with them can be monitored. In a further aspect, the invention also relates to a laser processing machine for processing, in particular cutting, metal, in particular plate-shaped workpieces using a laser beam with a laser beam power of at least 10 kW, with a laser processing head, from which the laser beam emerges in the direction of a workpiece, with a machine control for controlling the laser processing by means of laser processing parameters and for controlling the movement of the laser processing head and the workpiece relative to one another, and with an input device for manually entering parameter values of at least one laser processing parameter into the machine control, the machine control being programmed to check a manually entered input value to determine whether of laser processing with this input value, damage to the laser processing machine by the laser beam is to be expected, and if no damage is to be expected, the to accept the input value as the new parameter value of the laser processing parameter.

With such a laser processing machine, by checking the parameter values, damage to the laser processing machine during the processing operation can be avoided. The at least one laser processing parameter is preferably one or more of the following laser processing parameters: focus position of the laser beam, focus diameter of the laser beam, feed rate of the laser beam when processing the workpiece, nozzle diameter.

An upper and/or a lower limit value of the at least one laser processing parameter for damage-free laser processing is preferably stored in the machine control, particularly advantageously as an absolute or percentage deviation from a standard value of the laser processing parameter. Damage-critical value combinations of at least two laser processing parameters can also be stored in the machine control.

Further features and advantages of the invention result from the following description of exemplary embodiments of the invention, with reference to the figures in FIG Drawing showing details essential to the invention and from the claims. The individual features can each be implemented individually or together in any combination in a variant of the invention.

Exemplary embodiments are shown in the schematic drawing and are explained below. In the figures, the same reference symbols denote the same or corresponding features. Show it:

1 shows a laser processing machine according to the invention, here using the example of a laser cutting machine, for carrying out the method according to the invention for laser cutting plate-shaped workpieces;

Figs. 2a, 2b a longitudinal section of a cutting nozzle of a laser cutting head shown in FIG. 1, from which a laser beam exits with a focus position that is too high (FIG. 2a) and a focus position that is too low (FIG. 2b);

Figs. 3a, 3b each an input mask of an input device for manual input of parameter values of several laser processing parameters; and

4 schematically shows the approach of the laser cutting head to a workpiece at a minimum approach speed.

The laser processing machine 1 shown in FIG. 1 is used for laser cutting of plate-shaped workpieces (e.g. sheet metal) 2 using a laser beam 3 with a beam power of at least 10 kW and is therefore also referred to below as a laser cutting machine.

The laser cutting machine 1 has a laser beam generator 4 for generating the laser beam 3, a laser cutting head 5 and a workpiece support 6 on which the workpiece 2 is arranged. The laser beam 3 is generated in the laser beam generator 4 and is guided from the laser beam generator 4 to the laser cutting head 5 by means of a fiber-optic cable (not shown) or deflection mirrors (not shown). The laser beam 3 is directed onto the workpiece 2 by means of focusing optics arranged in the laser cutting head 5 . The laser beam 3 occurs in a z-direction out of the laser cutting head 5 and strikes the workpiece 2 in the z direction. The laser cutting head 5 can be moved above the workpiece 2 in the x and y direction by means of a drive 7 . The laser cutting machine 1 is also supplied with cutting gases 8, such as oxygen and nitrogen. The cutting gas 8 is supplied to a cutting nozzle 9 of the laser cutting head 5, from the nozzle opening of which it emerges together with the laser beam 3.

The laser cutting machine 1 also includes a machine controller 10 for controlling laser cutting parameters of the laser beam 3 and for controlling the drive 7 in order to move the laser cutting head 5 together with the exiting laser beam 3 according to a predetermined cutting contour 11 relative to the workpiece 2 at a feed rate v. Through an input device (e.g.

HMI) 12, parameter values of the laser cutting parameters are entered manually into the machine control 10. The machine control 10 is programmed to check a manually entered input value to determine whether damage to the laser processing machine 1 by the laser beam 3 is to be expected during laser processing with this input value or not. If no damage is to be expected, the input value is accepted by the machine control 10 as the new parameter value of the laser processing parameter.

2a shows the cutting nozzle 9 from which the laser beam 3 emerges in the direction of the workpiece 2. FIG. The focal position ZF of the laser beam 3 with focal diameter dp is, as seen from the workpiece 2, above the permissible upper focal position, ie the laser beam 3 has a too high focal position ZF. As a result, the laser beam 3 in the nozzle opening 13 runs divergently in the beam direction in such a way that it strikes the inner wall 14 of the nozzle at the lower end of the nozzle opening 13 . The diameter of the laser beam 3 at the lower end (z _u ) of the nozzle opening 13 is therefore larger than the opening diameter Dk of the nozzle opening 13.

In FIG. 2b, the focus position Zf of the laser beam 3 with focus diameter df, as seen from the workpiece 2, is below the permissible lower focus position, ie the laser beam 3 has a focus position ZF that is too low. As a result, the laser beam 3 converges in the nozzle opening 13 in the beam direction in such a way that it is at the upper end (zo) of the nozzle opening 13 meets the inner opening wall 14. The diameter of the laser beam 3 at the upper end of the nozzle opening 13 is therefore larger than the opening diameter Dk of the nozzle opening 13.

In Figs. 2a, 2b, the laser beam 3 strikes or touches the inner opening wall 14, so that the cutting nozzle 9 is damaged by the thermal stress of the laser radiation. In the machine control 10, the permissible upper and lower focus positions are defined as limit values of the laser cutting parameter “focus position ZF” for damage-free laser processing or are calculated from the parameter values of focus position, focus diameter and beam quality. If the operator enters an input value for the focus position ZF via the input device 12 that is greater than the upper limit value or smaller than the lower limit value, this is not accepted by the machine control system, or only with a warning, or it is set to a parameter value that is not critical to damage, in particular to the nearest parameter value that is not critical to damage , corrected.

3a, 3b each show an input mask 15 of the input device 12, via which the parameter values of several laser processing parameters (here only as an example: focus position ZF and focus diameter dF) are entered manually into the machine control 10. An input value for the focus position ZF can be entered via a first mask field 15a and an input value for the focus diameter dF can be entered via a second mask field 15b.

In the exemplary embodiment shown in Fig. 3a, the input value "-28 mm" of the focus position ZF is outside the permissible value range of the upper and lower limit values for the set focus diameter of 840 pm, so that the laser beam 3 hits the inner opening wall 14 of the cutting nozzle 9 or would strip what the operator in the mask field 15a by a symbolic warning sign 16 and a warning message "Collision jet nozzle!" Is displayed. The input value "-28 mm" recognized as impermissible is consequently not accepted by the machine control 10 . In the exemplary embodiment shown in FIG. 3b, the input value “7500 pm” of the focus position ZF is beyond the upper limit values for all permissible focus diameters and is therefore rejected by the machine control 10, which is indicated to the operator by an x symbol 17. Due to the impermissible focus position ZF, the set focus position ZF of -15 mm cannot be checked, which is indicated to the operator by a question mark symbol 18. Alternatively or additionally, the "question mark" can also indicate a large deviation from the original value or a similarity comparison can be made; for example, the comma may simply have been forgotten in the first mask field 15a: -15 mm instead of -1.5 mm.

4 schematically shows a workpiece 2 (e.g. sheet metal) on the workpiece support 6. With the laser beam 3 initially switched off, the laser cutting head 5 is moved towards the workpiece 2 over a first section si. The laser beam 3 is then switched on and the laser processing head 5 is moved up to an edge of the workpiece 2 over a second section S2. The minimum approach speed Vmin, with which the laser cutting head 5 is moved towards the workpiece 2, is calculated in particular as a function of the laser beam power and/or a focus diameter dF of the laser beam 3.

This is because the laser beam 3 could be deflected in the direction of a cladding or housing 20 of the laser cutting machine 1 as a result of reflection from a slug 19 which originates from previous processing and has got stuck on the workpiece support 6 . Such a reflection at the slug 19 can take place, for example, when a residual grid is cut up. When cutting up the residual skeleton, the laser cutting head 5 with the ignited laser beam 3 is moved from the outside to a workpiece edge. During the start-up, the laser beam 3 can hit the slug 19 and be deflected in the direction of the paneling 20 . In this case, the laser beam 3 must not hit the paneling 20 within a predetermined standing time, in order to avoid damage.

For example, the service life of the cladding is 5 s with a laser power of 12 kW. If a safety time of 2 s, for example, is to be given, it must be ensured that the laser beam is aimed at the cladding for a maximum of 3 s at 12 kW 20 reached. If the laser beam 3 is ignited 6 mm before the edge of the workpiece, for example, it can be derived from this how high the minimum approach speed Vmin of the laser cutting head 5 must be on the approach distance si, S2 in order not to exceed the 3 s exposure time. In this example, the minimum approach speed of the laser cutting head 5 with a laser power of 12 kW is: Vmin=6 mm/3s=2 mm/s=0.12 m/min.

Claims

patent claims

1 . Method for processing, in particular cutting, metallic, in particular plate-shaped workpieces (2) using a laser beam (3) of a laser processing machine (1) with a laser beam power of at least 10 kW, the laser processing being controlled by a machine controller (10) using at least one laser processing parameter, the parameter value of which can be entered manually, characterized in that an input value entered manually for the at least one laser processing parameter is checked by the machine controller (10) to determine whether the laser processing machine (1) will be damaged by the laser beam (3) during laser processing with this input value is to be expected, and that in the event that no damage is to be expected, the input value is accepted by the machine control (10) as the new parameter value of the laser processing parameter.

2. The method as claimed in claim 1, characterized in that in the event of damage to be expected, the input value is not accepted by the machine controller (10) or is accepted only with a warning.

3. The method according to claim 1, characterized in that if damage is to be expected, the input value of the machine control (10) is corrected to a damage-uncritical parameter value of the laser processing parameter, in particular to the nearest damage-uncritical parameter value.

4. The method according to claim 1, characterized in that in the event of expected damage, the input value of the machine control (10) is accepted unchanged as the new parameter value of the laser processing parameter and the parameter value of at least one other Laser processing parameter is changed by the machine control (10) in such a way that both the input value of a laser processing parameter and the changed parameter value of the other laser processing parameter are not critical for damage.

5. The method according to any one of the preceding claims, characterized in that the at least one laser processing parameter is at least one of the following parameters: focus position (ZF) of the laser beam (3), focus diameter (dp) of the laser beam (3), feed rate (v) of the laser beam (3) when processing a workpiece (2), minimum approach speed (vmin) of the laser beam (3) when approaching a workpiece (2), diameter of the cutting nozzle (Dk)

6. The method according to any one of the preceding claims, characterized in that an upper and/or a lower limit value of the at least one laser processing parameter for damage-free laser processing is defined in the machine control (10) and that the input value of the at least one laser processing parameter, if it is greater than is the upper limit value or smaller than the lower limit value, is not accepted by the machine control (10) or only with a warning, or is corrected by the machine control (10) to a parameter value that is not critical to damage, in particular to the nearest parameter value that is not critical to damage.

7. The method according to claim 5, characterized in that the upper and/or the lower limit value of the at least one laser processing parameter is defined as an absolute or percentage deviation from a standard value of the laser processing parameter.

8. The method according to any one of the preceding claims, characterized in that damage-critical value combinations of at least two laser processing parameters are defined in the machine control (10) and that the input value of the at least one laser processing parameter, if it is used together with the parameter value of the 16 other laser processing parameter represents a critical combination of values, is not accepted by the machine control (10) or only with a warning or is corrected by the machine control (10) to a damage-uncritical parameter value, in particular to the nearest damage-uncritical parameter value.

9. The method according to any one of the preceding claims, characterized in that in the machine control (10) a minimum approach speed (vmin) of the laser beam (3) for approaching a workpiece (2) depending on a laser power and/or a focus diameter of the laser beam (3 ) is specified.

10. Laser processing machine (1) for processing, in particular cutting, metal, in particular plate-shaped workpieces (2) using a laser beam (3) with a laser beam power of at least 10 kW, with a laser processing head (5) from which the laser beam (3) is directed in the direction exits onto a workpiece (2), with a machine controller (10) for controlling the laser processing by means of laser processing parameters and for controlling the movement of the laser processing head (5) and workpiece (2) relative to one another, and with an input device (12) for the manual input of parameter values at least one laser processing parameter into the machine control (10), the machine control (10) being programmed to check a manually entered input value to determine whether damage to the laser processing machine (1) by the laser beam (3) is to be expected during laser processing with this input value , and in case no damage is to be expected ment to accept the input value as the new parameter value of the laser processing parameter.

11. Laser processing machine according to claim 10, characterized in that an upper and/or a lower limit value of the at least one laser processing parameter (ZF) for damage-free laser processing is stored in the machine control (10). 17 Laser processing machine according to claim 11, characterized in that the upper and/or the lower limit value of the at least one laser processing parameter (ZF) are stored as an absolute or percentage deviation from a standard value of the laser processing parameter. Laser processing machine according to one of Claims 10 to 12, characterized in that damage-critical value combinations of at least two laser processing parameters are stored in the machine control (10).