DE10016534A1 - Dust protection for working laser unit, induces longitudinal gas flow towards workpiece and exerts ambient pressure in working region - Google Patents

Abstract

Ambient pressure is exerted in the working region (S'). A longitudinal gas flow towards the working region, is induced in a region (R1) located between the working region and the laser unit. An Independent claim is included for the corresponding apparatus. A further claim covers the entire laser processing apparatus with dust protection as described, and a workpiece feed system. Preferred features: During gas introduction, gas is removed from the neighborhood of the working region. The longitudinal gas flow is accelerated toward the working region. The region (R1) is located in a channel of a casing between the laser unit and the working region. The channel extends between a beam entrance opening and a beam exit opening of the casing. The process further includes supply of gas to, and its removal from the channel at separate internal locations, the quantity supplied being essentially that removed. The longitudinal gas flow is developed over the full cross section, and is directed towards the beam exit opening. A pressure obstruction is formed in a second region (R2) of the channel, between the first (R1) and the laser unit. Gas is supplied at opposed inlets perpendicular to the longitudinal axis in the first region, to form the longitudinal flow. Opposed inlets cover the entire cross section with flow. A separate peripheral gas flow is produced along the channel in the first region by at least one input. Flow is directed towards the working region. Gas is led off near the beam exit opening, preferably in at least two diametrally opposed directions. Lateral gas flow is produced in a third region (R3) of the channel, between the first region (R1) and the laser unit. The flow is produced between opposite openings in the side wall and covers a full cross section of the channel. Lateral flow takes place essentially perpendicular to the longitudinal central line of the channel. Gas is supplied and led away through opposed openings at essentially the same rates. Pressure is measured in at least one location in the casing and gas removal rate from the casing is controlled from the measurement. Pressure is maintained at \! 1 kPa relative to ambient, in the working region. The channel is non-circular in the first region. It is rectangular, especially square with openings in the corners. The channel constricts to cause flow acceleration.

Description

The present invention relates to laser material bear processing, in particular on a method and an apparatus to protect a laser unit from dust or fragments, the during the laser machining of a machining target or Work piece or substrate arise in the machining area.

The present invention is particularly useful in combination hang with a device for laser engraving or -to mark. Hence the technical background of the Erfin and objectives and embodiments thereof with reference to Laser engraving devices described. The invention can ever but also in connection with devices for any other kind of Laser material processing, for example other laser Surface treatment, laser cutting and laser welding find application.

As for example in DE-A1-43 38 774 or DE-A1-44 05 203 generally includes a laser engraving device a laser unit and a workpiece guide device, which are arranged below the laser unit and for guiding of a workpiece is formed past the laser unit. The laser unit includes one for generating a laser beam trained laser section and a control section cut, which is designed to the laser radiation on the  workpiece to be provided with laser engraved markings direct and focus. When the workpiece is laser machined material from the workpiece in the form of small particles worn away. These particles or fragments call together Dust emerges either on the surface of the workpiece is liable or as a result of bombardment with laser radiation from Workpiece flies away. In such a device it is important to prevent dust from entering the laser unit, because the presence of dust may cause ver deterioration or destruction of any opti contained therein component.

In a laser engraving device disclosed in EP-A1-0 085 484 tion becomes an air curtain arrangement not described any further connection with a hanging bellows between the laser unit and an underlying engraving area used to prevent dust from entering the laser unit prevent. Such an arrangement may be sufficient to be in the Ambient air contains dust from entering the lase to keep purity. However, dust or debris, those in the engraving area due to material coming from the workpiece is removed, produced, but still into the laser occur. This problem is with the high precision four tightened when the distance from the laser unit to the Engraving area must be reduced, thereby reducing the dust source closer to the sensitive laser unit becomes.

Obviously the situation would be worse if the laser unit would be located below the engraving area re, because gravity is a buildup of dust on the la would promote this unit. If two opposite sides  to provide engraved markings on a workpiece are precise, especially the markings on both sides must be arranged relative to each other, it is advantageous or even necessary to graze the workpiece from both sides four. If the workpiece is between the engraving operations the positional relationship between easily lost on both sides. This problem is ver sharpens when engraving a continuous web of material is because the turning process is difficult and requires a lot of space does. Such a turning process is often not with high pros to agree production speeds. Furthermore is by the use of two consecutive engraving stations to engrave a corresponding side of the web and one intermediate turning station for turning the web of the The distance between the engraving stations was so large that it swelled rig is a positional relationship between the marks on the opposite side of the track hold.

When finally that with the laser engraved markings too provided workpiece small, light and / or made of flexible dimensions is manufactured, a conventional air curtain Arrangement in an undesirable manner the position or shape of the Change the workpiece during the engraving process.

It is an object of the present invention to achieve the above To prevent or at least mitigate disadvantages and a improved method and device for protecting a La unit against dust during the machining of a workpiece or to provide substrate in the processing area. The The object of the invention is particularly aimed at the entry to prevent dust from entering the laser unit  and the high-precision laser processing of everyone Allow types of workpieces.

Another object of the invention is to provide a mini paint influence on the position and shape of the workpiece during processing in the processing area to practice.

Another object of the invention is the laser machining from either side, or both sides, of a workpiece.

These and other goals have been described in the following Be writing emerges through a procedure and a device tion as achieved in the independent claims are written. Preferred embodiments of the invention are the subject of the dependent claims.

By generating an ambient pressure in the machining area the forces acting on the workpiece become mini lubricated. Therefore, taking into account the Ma ßes dust protection of all kinds of workpieces be processed, even small, light and / or flexible work pieces. By generating a longitudinal gas flow, the one in a first area between the machining area and the laser unit directed towards the processing area dust becomes effective from movement to the laser unit hindered. Furthermore, the procedure and the pre allows direction of the invention, the laser processing from below the Workpiece, since the longitudinal guest flow in the first area can be arranged so that it is contrary to the Gravitati  force on the dust that is on the workpiece during loading work is created, works.

In a first embodiment, gas is simultaneously in the Dissipated near the processing area and the first loading rich between the machining area and the laser unit fed, causing the ambient pressure in the machining area as well as the gas flow directed towards the processing area is fathered. Preferably, the longitudinal gas flow becomes Machining area accelerated to the suitability of the Gas flow, the gravitational force acting on the dust ent counteract, further improve.

In another embodiment, a housing is between the Laser unit and the processing area arranged. A Ka nal extends within the housing from one of the La Ser unit facing radiation inlet opening and a Radiation outlet opening facing the processing area and is generally located in the vicinity thereof. Gas will at the same time at different points in the channel led and removed from this. By the gas supply and -discharge rates in the housing are balanced, is secured represents that the pressure at the radiation outlet opening and practically the same in the machining area Ambient pressure can be maintained. With a simple and effective same arrangement will equalize the gas supply and -discharge rates caused by controlling the gas discharge rate, so that essentially ambient pressure in the machining area is produced.

The gas discharge is advantageously in the vicinity of the jet tion outlet opening causes such a discharge the tax  tion of the pressure at the radiation outlet opening is facilitated. In addition, dust can be generated from the area around the radiation outlet opening can be removed. The workpiece can therefore be selected be cleaned of dust after processing.

Preferably the longitudinal gas flow becomes substantially over a full cross section of the channel in the first area generated. In one embodiment, this is through the feed of gas in the first area by at least a pair of opposite gas inlet flows which cooperate to the gas flow towards the processing area testify. Preferably the opposite ones are painted over Gas inlet flows a full cross section of the channel in the first Area. When entering the canal, they are contrary th gas inlet streams preferably substantially perpendicular directed to the longitudinal center line of the channel so that they meet and together the longitudinal gas Form current over the entire cross section of the channel.

In another embodiment, a peripheral gas stream separated along a peripheral channel area in the first Be richly generated. This is preferably achieved in that one or more gas flows from the channel periphery to the Machining area. Such gas flows work the formation of suction areas near the canal walls against, especially in its corners. Furthermore, such Gas flows have a supporting effect in that they are generated Dust is moved from the workpiece to the radiation outlet opening, where it is effectively removed.

Gas is preferably diametrically opposed in at least two set directions in the vicinity of the radiation outlet opening  dissipated. This arrangement allows sufficient control tion of the pressure in the processing area, as well as an effective Removal of dust from the processing area.

In a further embodiment, a pressure lock in generated a second region of the channel, preferably between between the first area and the laser unit. The pressure lock right, d. H. an area of higher pressure, from the machining area seen, acts supportive to dust from reaching the La holding unit.

In a further embodiment, a lateral gas flow generated in a third area in the channel, preferably between between the first area and the laser unit. The lateral Gas flow is between opposite openings in one Sidewall region of the channel generated, preferably in the Form of a gas curtain that covers a full cross section of the Ka nals sweeps in the lateral direction. All of them Dust covering the first area and, if present, the crosses the second area, is significantly slowed down and will effectively removed by such a lateral gas flow, vor the lateral gas flow is preferably adjusted by equalizing the corresponding gas supply and discharge rates generated so that the lateral gas flow is prevented from doing so with the flow interaction field in the first area and this is possible annoying to disturb.

In one embodiment, the channel is non-circular shaped cross-section, at least in the first area. This Arrangement prevents any formation of swirling gas movement in the first area. Such a swirling gas movement, at for example around the longitudinal axis of the channel, a  have a central low-pressure zone in which dust accumulates Laser unit could move. Preferably the cross is cut polygonal. To the formation of suction areas in the vicinity he channel walls, especially in the corners of the polygon, to counteract, are preferably flow-generating openings provided in a side wall region of the channel preferably in the corners. Each flow-producing opening has a shape and position to flow a gas along a peri area of the channel towards the processing area testify.

The following is a preferred embodiment of the invention tion with reference to the accompanying schematic drawings described.

Fig. 1 is a side view of a laser engraving device in an arrangement for the manufacture of beverage closures, the laser engraving device having a dust protection device according to the invention.

FIG. 2 is a side view of the dust protection device of FIG. 1.

Fig. 3 is a cross sectional view taken along the centerline of the dust protection device of FIG. 2.

Fig. 4 corresponds to Fig. 3 and illustrates schematically Be rich different gas characteristics in the interior of the dust protection device.

Fig. 5 is a perspective view of the Staubschutzvor direction of Figs. 2-4.

Fig. 6 is a slightly inclined rear view of the dust protection device of Fig. 5.

Fig. 1 shows part of an arrangement for the production of marked closures or opening rings for use in the lid surfaces of beverage cans (not shown). A thin metal strip 5 is supplied from a supply 1 to a Lase unit 2 , which is supported by a carrier part 3 , and finally leads to a closure-generating unit 4 , which is of a known type and closure pieces by pushing and punching the strip S is generated (see, for example, the treatise "This is PLM Fosie", published by the company of the applicant PLM Fosie AB in the mid-1990s). The strip S is guided when passing the laser unit 2 by a guide device 5 and supplied by the supply 1 with the aid of a feed means (not shown) which is provided in connection with the closure-generating unit 4 . The laser unit 2 is a high-performance and high-speed type and is suitable for producing engravings or markings in the surface of the strip 5 . This laser unit 2 includes a laser section 2 ', which is set up to generate laser radiation of a suitable wavelength, and a so-called steering section 2 ", which is used to receive the laser radiation from the laser section 2 ' and to focus and steer the generated radiation onto a specific one Is set up on the surface of the strip S. In this way, a laser processing surface S '( FIGS. 2-4) is formed on the surface of the strip S.

Because the closure available for the markings If the surface is very small, the laser radiation must be precise the strip S must be positioned and the strip S must also precisely positioned during the laser engraving process become. Generally, the strip S is made of aluminum with a thickness of about 0.24 mm and a width of about 67 mm. Such a strip S becomes itself under the one flow of relatively small forces acting on the surface bend.

Between the steering portion 2 "and the guide means 5, a dust protection device 6 is provided. The dust protection device 6 is in communication with a unit 7 for controlling and effecting the simultaneous to driving and discharge of air to and processing by the Staubschutzvorrich 6, as in the following with reference to FIGS. 2-4 be written is. The air control unit 7 comprises a main control means 7 a, for example. a computer, an air pumping device 7 ', for example., a fan or a pump, an air suction means 7 ", for example. a blower or Pump and a high-pressure device 7 ''', for example a compressor. The main control device 7 A can be connected to one or more pressure sensors, as will be described below.

As shown in more detail in FIGS. 2-4, the dust comprises device 6, a housing 8 having a flange 9 at one he most end for direct attachment to the steering section 2 '(indicated with dashed lines in Fig. 2-4) with the aid of screws or the like (not shown) extending through holes (not shown) in the flange 9. A longitudinal channel 11 extends from a radiation inlet opening 12 at the first end to a radiation outlet opening 13 at the opposite second end State is the radiation outlet opening 13 facing the processing surface S 'and radiation is transmitted through the channel 11 between the steering section 2 "and the surface of the strip S (indicated by double-dashed lines in Fig. 2-4). The housing 8 has an observation window W, which allows the inspection of the channel 11 during the operation of the dust protection device 6 . The second end may or may not be connected to the guide device 5 (only shown in FIG. 1). The distance from the radiation outlet opening 13 to the strip surface is generally less than one or two centimeters.

As shown in Fig. 3, two opposite air inlet openings or apertures 16 , 17 are formed in a side band region of the channel 11 . In the embodiment shown, as shown in FIG. 6, the channel 11 is delimited by four side walls and generally has a square or rectangular cross section in the lateral direction. The air inlet openings 16 , 17 , each of which are identical in shape and dimensions, each extend over a corresponding side wall 14 , 15 of the rectangular channel 11 . The openings 16 , 17 communicate with a corresponding air inlet chamber 18 , 19 , which each have a pin 20 , 21 for connection to the air pump device 7 'with the aid of hoses H ₁ or the like ( FIG. 1).

Referring to Fig. 3, two opposite air outlet openings or apertures 22 , 23 in the side walls 14 , 15 in the vicinity of the radiation outlet opening 13 are formed. The air outlet openings 22 , 23 , which are each identical in shape and dimensions, each extend over a corresponding side wall 14 , 15 of the rectangular channel 11 . The openings 22 , 23 communicate with a corresponding air outlet chamber 24 , 25 , which each have a pin 26 , 27 for connection to the air suction device 7 "with the aid of hoses H2 or the like ( FIG. 1).

In operation, the air pump device 7 'leads air continuously and symmetrically to the air inlet openings 16 , 17 . In this way, two opposite symmetrical air flows that are directed laterally to the center of the channel 11 , as shown by the arrows in Fig. 3, through the air inlet openings 16 , 17 generated. At the same time, air is drawn out symmetrically in two opposite directions, as shown by arrows in FIG. 3, from an area near the radiation outlet opening 13 through the two opposite air outlet openings 22 , 23rd Therefore, the air suction unit 7 "continuously sucks air through the air outlet openings 22 , 23 , whereby an area R0, indicated schematically in FIG. 4, is generated with essentially ambient pressure. In this way, ambient pressure at the radiation outlet opening 13 and at the processing surface S ' The air streams entering through the openings 16 , 17 meet and form a composite air stream in the longitudinal or vertical direction towards the radiation outlet opening 13 and the processing surface S 'in a region R1 indicated in Fig. 4. Since the openings 16 , 17 extend over a corre sponding side of the rectangular duct 11 , the longitudinal air flow is generated substantially over the entire cross section of the duct.

In the embodiment shown, the channel walls 14 , 15 are inclined in a region R1 to the center line L of the channel 11 , so that the cross section is continuously reduced to the radiation opening 13 . In this arrangement, the longitudinal air flow to the radiation outlet opening 13 is accelerated in the region R1. It has been found that this improves the ability of the device 6 for protecting the steering section 2 "from the dust generated on the processing surface S '.

It has been found that for optimum operation the Strahlungsauslaßöffnungen 22, should be 23 inclined to the center line L in front of preferably at an angle of about 30 ° -60 ° th, so that the openings 22, facing 23 to a certain degree of Strahlungsauslaßöffnung 13 are. It has been found that this improves the ability to remove dust from the processing surface and the ability to generate a substantially uniform ambient pressure in the region R0 at the opening 13 . In order to further improve the uniformity of the pressure distribution in the region R0, the entire surface of the openings 22 , 23 should be approximately 2/3 of the surface of the radiation outlet opening 13 .

As shown in FIG. 4, a region of still air with a comparatively high pressure is generated in the duct immediately behind the region R1. Thus, a pressure lock is generated in the loading area R2, ie a pressure gradient with a pressure increasing towards the radiation inlet opening 12 . This pressure lock acts to prevent dust from reaching the steering section 2 ".

Suction areas can form in some channel geometries, in particular in the corners of the channel 11 . In such suction areas or silent areas, dust could slide along the walls of the channel 11 and thus overcome the area R1. Therefore, as shown in Figs. 2 and 6, a number of flow-generating passages 28 mün in the channel 11 , between the radiation inlet opening 12 and the air inlet openings 16 , 17 are provided. The passages 28 are set up to form currents J, which are directed to a center P in the processing surface S ', ie on the strip surface, as indicated by the simple arrows in FIGS. 3 and 4. Specifically, five passages 28 are formed in each lateral corner of the channel 11 , as shown in FIG. 6. The twenty passages 28 communicate with a common annular chamber 29 which is connectable to the Hockdruckein device 7 '''of the air control unit 7 , for. B. with the help of a hose H3 ( Fig. 1). Due to the distribution inherent in the generated air streams J, an air stream is generated along the duct walls. This peripheral air flow destroys the suction areas mentioned above. The streams J have the additional task of breaking away dust particles which are generated on the processing surface S 'during the engraving process.

The dust protection device according to the preferred embodiment of FIGS. 1-6 comprises an additional dust protection arrangement 30 . This arrangement 30 generates a lateral air curtain over the full cross section of the channel 11 in an area R3 (indicated in FIG. 4) between the area R2 and the radiation inlet opening 12 . This lateral air curtain is for detecting and removing all dust that crosses the areas R1 and R2, e.g. B. heavy particles, directed. As shown in FIG. 3, two opposite openings or apertures 31 , 32 are formed in a side wall region of the channel 11 . The openings 31 , 32 extend over a corresponding side wall of the rectangular channel 11 . The openings 31 , 32 communicate with a corresponding air chamber 33 , 34 , which each have a pin 35 , 36 for connection to the air control unit 7 with the aid of a corresponding hose H1 ', H2' or the like ( FIG. 1). The opening 31 is connected to the pump device 7 'and has a supply beak 31 ' extending into the channel 11 . The opening 32 is connected to the air suction means "connected 7, and has a portion extending in the Chan nel 11 receiving beak 32 '. The versor supply beak 31' is formed to form the incoming air to a lateral curtain, and the Aufnahmeschna bel 32 ', which is somewhat larger in the longitudinal direction, is arranged to receive essentially all of the air leaving the beak 31 '. In operation, the air supply and discharge rates through the openings 31 , 32 are substantially equalized, so that the lateral air flow with mini painter interaction with the outer areas R0-R2 in channel 11 is operated.

The embodiment shown in the figures was used in a laser processing apparatus with satisfactory results. The air pump device 7 'supplies air at a rate of approximately 10,000 to 30,000 l / min to the openings 16 , 17 , 31 , evenly distributed between these three. The high pressure device 7 '''supplies air at a pressure of 0.15-0.4 MPa (1.5-4 bar) to the annular chamber 29 , where air is supplied to the flow-generating passages 28 , each of which has a diameter of approximately 1.5 mm, in uniform distribution. At the same time, the air suction device 7 "is controlled by means of the main control device 7 A for discharging air from the openings 22 , 23 , 32. The air flows are controlled in such a way that essentially ambient pressure at the radiation outlet opening 13 , and thereby also at the processing area S It is produced on the strip S. In one embodiment, this is achieved without feedback control by simply compensating for the air flows entering and exiting the housing 8. In another embodiment, the removal of air is actively carried out by the control unit 7 A on the basis controls the signals from one or more pressure sensors (sensors 37 , 38 in Fig. 3) that are set up in connection with channel 11. Alternatively, all air flows into and out of housing 8 can be individually and actively controlled by means of the control approximately 7 A can be controlled.

The size of the pressure deviation from the environment that can be tolerated at the opening 13 depends on the type of workpiece. With the present workpiece, the pressure at the radiation outlet opening 13 is preferably controlled within ± 1 kPa (± 10 mbar) of the ambient pressure in order not to undesirably impair the position or shape of the strip S during the engraving process.

As shown in FIGS. 3-6, the dust protection device 6 comprises an additional cleaning arrangement 40 . The cleaning arrangement 40 is provided at the first end of the housing 8 , ie facing the steering section 2 ". The cleaning arrangement 40 comprises two lateral hollow tubes 41 , 42 which are connected to an outer connection 43 ( FIG. 6) of the housing 8 . The connection 43 is in turn connected to the high pressure device 7 "" by means of a hose H3 'or the like ( Fig. 1) One or more rows of holes 44 are provided in the peripheral wall of each tube 41 , 42. Each row of holes Chern 44 is offset relative to the lateral direction and is thereby able to direct air toward the radiation inlet opening 12 in order to remove dust deposited on the steering section 2 ″. Preferably, the air control unit 7 is operated to shut off the air through the cleaning assembly 40 so that air is emitted in short bursts from the rows of holes 44 ( FIG. 5). The cleaning arrangement 40 is preferably used whenever dust could have been deposited on the steering section 2 ″, for example after the laser engraving device has restarted after a shutdown or interruption in production.

The dust protection device 6 can be modified in a variety of ways without leaving the scope of protection defined in the claims. E.g. any number of openings could be provided for generating the longitudinal air flow in the area R1 and the lateral air flow in the area R3. Further air outlet openings could also be provided in order to improve the pressure control at the radiation outlet opening 13 . Furthermore, a different arrangement of the air openings could be used to achieve the desired flow distribution in the channel 11 . The above also applies if the flow-generating openings 28 .

The air control unit 7 may include some type of filter (not shown) to remove dust particles in the air flow from the dust protection device 6 . Gases other than air can also be used.

In addition to the dust protection device 6 described above, the invention also relates to a method for protecting a laser device 2 from dust which is generated during the laser processing of a workpiece, in this case a strip S., in a processing area S '. In the broadest sense, this method comprises the steps of generating essential ambient pressure in the processing area S 'and generating a longitudinal gas flow in an area R1 between the processing area S' and the laser unit 2 , which is directed towards the processing area S '.

The inventive device and method can be used for protection other types of marking units for non-mechanical Serve workpieces.

Claims (42)

1. A method for protecting a laser unit ( 2 ) from dust during the laser machining of a machining target or workpiece (S) in a machining area (S '), comprising the steps:
Generation of essentially ambient pressure in the machining area (S '), and
Generation of a longitudinal gas flow directed towards the processing area (S ') in a first area (R1) between the processing area (S') and the laser unit ( 2 ). 2. The method of claim 1, further comprising the steps of simultaneously supplying gas to the first region (R1) between the processing region (S ') and the laser unit ( 2 ) and discharging the gas in the vicinity of the processing region (S'). 3. The method of claim 1 or 2, wherein the longitudinal Gas flow accelerated to the processing area (S ') becomes. 4. The method according to any one of claims 1 to 3, wherein the loading area (R1) is arranged in a channel ( 11 ) of a housing ( 8 ) which is arranged between the laser unit ( 2 ) and the processing area (S ') , wherein the channel ( 11 ) extends between a radiation inlet opening ( 12 ) and a radiation outlet opening ( 13 ) of the housing ( 8 ), the method further comprising the steps of simultaneously supplying gas to and removing gas from the channel ( 11 ) at separate locations therein, the amount of gas supplied from the channel ( 11 ) being approximately equal to the amount of gas discharged from the channel ( 11 ). 5. The method according to claim 4, wherein the longitudinal gas flow is generated substantially over a full cross section of the channel ( 11 ) and is directed towards the radiation outlet opening ( 13 ). 6. The method of claim 4 or 5, further comprising the step of creating a pressure barrier in a second region (R2) in the channel ( 11 ). 7. The method according to claim 6, wherein the second region (R2) is arranged between the first region (R1) and the laser unit ( 2 ). 8. The method according to any one of claims 4 to 7, wherein gas in the first region (R1) in at least one pair of dia metrically opposite gas inlet flows leading to the Bil extension of the longitudinal towards the machining area (S ') directed gas flow interact, is supplied. 9. The method according to claim 8, wherein the opposite gas inlet flows upon entry into the channel ( 11 ) are directed substantially perpendicular to a longitudinal center line (L) of the channel ( 11 ). 10. The method according to claim 8 or 9, wherein the opposing gas inlet streams together sweep a full cross section of the channel ( 11 ). 11. The method according to any one of claims 4 to 10, further comprising the step of separately generating a peripheral gas flow along a peripheral region of the channel ( 11 ) in the first region (R1), the peripheral gas flow to the processing region (S ' ) is directed towards it. 12. The method of claim 11, wherein at least one gas current (J) generated to form the peripheral gas stream and is directed towards the processing area (S '). 13. The method according to any one of claims 4 to 12, wherein gas in the vicinity of the radiation outlet opening ( 13 ) is preferably discharged in at least two diametrically opposite directions. 14. The method according to any one of claims 4 to 13, which further comprises the step of generating a lateral gas flow in a third region (R3) in the channel ( 11 ) between opposite openings ( 31 , 32 ) in a side wall region of the channel ( 11 ) includes. 15. The method according to claim 14, wherein the third region (R3) between the first region (R1) and the laser unit ( 2 ) is arranged. 16. The method according to claim 14 or 15, wherein the lateral gas flow sweeps over a full cross section of the channel ( 11 ). 17. The method according to any one of claims 14 to 16, wherein the lateral gas flow is substantially perpendicular to a lon gitudinal center line (L) of the channel ( 11 ). 18. The method according to any one of claims 14 to 17, wherein gas through the opposite openings ( 31 , 32 ) at we substantially the same rates the channel ( 11 ) is supplied and removed therefrom. 19. The method according to any one of claims 4 to 18, further comprising the steps of measuring the pressure at at least one point in the housing ( 8 ) and controlling the gas discharge from the housing ( 8 ) on the basis of the measured pressure. 20. The method according to any one of claims 1 to 19, wherein the Pressure in the machining area (S ') within ± 1 kPa is maintained relative to the ambient pressure. 21. Dust protection device for arrangement in a laser processing device, the dust protection device defining a channel ( 11 ) which extends from a radiation inlet opening ( 12 ) to a radiation outlet opening ( 13 ) for transmitting radiation from a laser unit ( 2 ) to a processing area (S ') of the laser processing device, a gas control unit ( 7 ) being set up in fluid communication with the channel ( 11 ), the gas control unit ( 7 ) for controlling the maintenance of a longitudinal gas flow directed towards the radiation outlet opening ( 13 ) in a first loading rich (R1) between the radiation outlet opening ( 13 ) and the radiation inlet opening ( 12 ), as well as to maintain essentially ambient pressure at the radiation outlet opening ( 13 ) can be controlled. 22. Dust protection device according to claim 21, wherein the gas control unit ( 7 ) for simultaneous gas supply and gas discharge from the channel ( 11 ) is set up in substantially equal amounts. 23. Dust protection device according to claim 21 or 22, the wei terhin at least one gas outlet opening ( 22 , 23 ) in a first side wall region of the channel ( 11 ) in the vicinity of the radiation outlet opening ( 13 ) and at least one gas inlet opening ( 16 , 17 ) in one of the Radiation outlet opening ( 13 ) comprises a spaced apart second side wall area, the gas outlet and inlet openings ( 16 , 17 , 22 , 23 ) being connected to the gas control unit ( 7 ), which are used for gas supply to the gas inlet opening ( 16 , 17 ) and gas discharge from the gas outlet opening ( 22 , 23 ) is controllable. 24. Dust protection device according to claim 23, which comprises at least one pair of gas inlet openings ( 16 , 17 ) which are arranged to generate at least one pair of diametrically opposed gas flows which cooperate to form the longitudinal gas flow directed towards the radiation outlet opening ( 13 ). 25. Dust protection device according to claim 24, wherein the opposite gas flows to form a pressure barrier in a second region (R2) between the first region (R1) and the radiation inlet opening ( 12 ) are controlled when the latter is connected to the laser unit ( 2 ) . 26. The dust protection device according to claim 24 or 25, wherein the opposite gas flows upon exiting the pair of gas inlet openings ( 16 , 17 ) are directed substantially perpendicular to a longitudinal center line of the channel ( 11 ). 27. Dust protection device according to one of claims 24 to 26, wherein the gas inlet openings ( 16 , 17 ) are designed so that the opposite gas flows together sweep a full cross section of the channel ( 11 ), so that the longitudinal gas flow substantially over a full cross section of the Channel ( 11 ) is maintained. 28. Dust protection device according to claim 27, wherein the cross section of the channel ( 11 ) has the shape of a square and each of the gas inlet openings ( 16 , 17 ) extends along a corresponding side of the square. 29. Dust protection device according to one of claims 23 to 28, which comprises at least a pair of gas outlet openings ( 22 , 23 ) which are arranged diametrically opposite each other in the vicinity of the radiation outlet opening ( 13 ). 30. Dust protection device according to claim 29, wherein the gas outlet openings ( 22 , 23 ) to the radiation outlet opening ( 13 ) are inclined. 31, dust-proofing device according to claim 29 or 30, wherein the total surface of the Strahlungsauslaßöffnung (13) facing the gas outlet openings (22, 23) is about 2/3 of the surface of the Strahlungsauslaßöffnung (13). 32. Dust protection device according to one of claims 21 to 31, further comprising at least one pressure sensor ( 37 , 38 ) arranged in connection with the channel ( 11 ) for providing pressure data, the gas control unit ( 7 ) for controlling the gas discharge through the gas outlet opening ( 22 , 23 ) based on the print data. 33. Dust protection device according to one of claims 21 to 32, wherein the channel ( 11 ) has a non-circular cross section at least in the first region (R1). 34. Dust protection device according to one of claims 21 to 33, further comprising flow-generating openings ( 28 ) which are formed in a third side wall region of the channel ( 11 ), preferably in one of its corners, the gas control unit ( 7 ) for supplying gas through the flow-generating openings ( 28 ) for generating gas streams (J) directed towards the radiation outlet opening ( 13 ) is controllable, each flow-generating opening having a shape and arrangement for a peripheral gas stream along a peripheral region of the channel ( 11 ) at least in the first region To generate (R1). 35. Dust protection device according to claim 34, wherein the cross section of the channel ( 11 ) has the shape of a polygon, preferably a square, and at least one of the flow-generating openings ( 28 ) is provided in each corner of the polygon. 36. Dust protection device according to one of claims 21 to 35, wherein the channel ( 11 ) has a decreasing cross-section to the radiation outlet opening ( 13 ) at least in the first region (R1), so that the longitudinal gas flow to the radiation outlet opening ( 13 ) accelerates out becomes. 37. Dust protection device according to one of claims 21 to 36, further comprising at least one gas inlet opening ( 31 ) and at least one opposite gas outlet opening ( 32 ) in a third region (R3) of the channel ( 11 ), wherein the gas control unit ( 7 ) for gas supply Gas inlet opening ( 31 ) and gas discharge from the gas outlet opening ( 32 ) can be controlled in order to maintain a lateral gas flow in the third region, which runs essentially perpendicular to a longitudinal center line (L) of the channel ( 11 ). 38. Dust protection device according to claim 37, wherein the third region (R3) between the first region (R1) and the radiation inlet opening ( 12 ) is arranged. 39. Dust protection device according to claim 37 or 38, wherein the gas inlet and outlet openings ( 31 , 32 ) are designed such that the lateral gas flow sweeps over a full cross section of the channel ( 11 ). 40. Dust protection device according to one of claims 37 to 39, wherein the gas control unit ( 7 ) for simultaneous gas supply and gas discharge from the gas inlet and outlet openings ( 31 , 32 ) is set up in substantially equal amounts. 41. Dust protection device according to one of claims 21 to 40, wherein the gas control unit ( 7 ) for maintaining the pressure at the radiation outlet opening ( 13 ) is set up within ± 1 kPa relative to the ambient pressure. 42. Laser processing device comprising a laser unit, a guide unit ( 5 ) for guiding a workpiece or processing target (S) past a processing area (S ') past the laser unit ( 2 ) and a dust protection device according to one of claims 21 to 41, wherein the dust protection device is arranged between the laser unit ( 2 ) and the guide unit ( 5 ).