The present disclosure relates to the field of machining workpieces, specifically machining workpieces by turning. In particular, the disclosure relates to turning workpieces with a laser beam coupled into a fluid jet, i.e., with a fluid-jet guided laser beam. The disclosure respectively provides a method and an apparatus for machining a workpiece, wherein the machining comprises turning the workpiece. The method may be carried out by the apparatus, and the apparatus is configured to provide the fluid-jet guided laser beam.
Turning is a process of machining a workpiece, which comprises, for instance, using a cutting tool to cut into the workpiece, while the workpiece rotates. The cutting tool may thereby be moved linearly while the workpiece rotates, such that, for instance, the cutting tool describes a helix path on the workpiece surface. That is, conventional turning of a workpiece comprises rotating the workpiece around an axis of rotation, and at the same time machining the workpiece, for instance, cutting it with the cutting tool. The speed of turning the workpiece is determined by the rotational speed of rotating the workpiece. A conventional cutting tool may be a conventional laser.
The conventional turning has several disadvantages. For instance, not all materials can be easily turned in the conventional way, i.e., by using a conventional cutting tool. Some materials, like diamonds or superalloys, may be too hard for the cutting tool, while other materials, like PHYNOX or MAGIC GOLD, may be too brittle or too sensitive to the heat that is produced by the cutting tool during the turning of the workpiece. Furthermore, there are usually limitations to the workpiece size, which is still feasible for tuning the workpiece. Specifically, high aspect ratio workpieces are difficult to machine with conventional turning. Further, larger workpieces (with a larger volume and/or diameter) may be quite difficult to machine by turning w with a conventional laser. Finally, a surface roughness of a machined surface of the turned workpiece is often not satisfactory after conventional turning, i.e., the surface is often too rough and requires further processing steps like polishing.
Another drawback of the conventional turning is that this machining process cannot easily be integrated in a process flow, which also comprises other machining processes of the workpiece, for example, drilling, milling or engraving the workpiece (particularly the turned workpiece).
Therefore, embodiments of the invention aim at improving conventional ways of machining a workpiece by turning. An objective is, in particular, to provide a method and an apparatus, respectively, which can turn workpieces of many kinds of materials, even very hard and/or brittle materials and heat sensitive materials. The turning should be full-automatically performed. Further, it should be easy to integrate the turning with one or more other machining processes of the workpiece. The turning should further result in an improved surface roughness of the machined surface of the machined workpiece. In addition, it should be well feasible to perform turning also on larger workpieces. Finally, the time to machine a workpiece of a given precision, quality and shape should be reduced, while also reducing the tool consumption during the machining process. Embodiments of the invention should also allow the machining of new types of workpieces, such as turning of high-aspect ratio grooves into workpieces made of hard, brittle and/or heat-sensitive materials.
These and other objectives are achieved by the embodiments presented in the enclosed independent claims. Advantageous implementations of these embodiments are defined in the dependent claims.
In particular, the embodiments of the invention base generally on the use of an apparatus for implementing a method for machining a workpiece comprising turning the workpiece. The apparatus provides a laser beam that is guided in a fluid jet by internal reflection. This fluid-jet guided laser beam can efficiently turn the workpiece. Thereby, different orientations between the laser beam and the machined surface of the workpiece are possible according to embodiments of the invention. These embodiments enable the turning of even ultra-hard material workpieces and brittle or highly-heat-sensitive material workpieces with a very high precision, in particular, on high aspect ratio or complex geometries.
A first aspect provides a method for machining a workpiece, wherein the method is performed by an apparatus providing a fluid-jet guided laser beam, wherein the method comprises turning the workpiece, and wherein turning the workpiece comprises: rotating the workpiece around an axis of rotation during the machining; and providing the fluid-jet guided laser beam to a machined surface of the workpiece.
The workpiece may be continuously rotated during the turning, in particular during the machining of the workpiece. The fluid-jet guided laser beam enables the turning of workpieces of many kinds of materials, including very hard materials and brittle or very heat sensitive materials. The turning can be performed full-automatically with the apparatus. Improved results of turning the workpiece are achieved with the method of the first aspect compared to a conventional turning method that does not use of a fluid-jet guided laser beam. For instance, in terms of speed, precision, and surface roughness, or accessibility of the fluid jet.
The workpiece may have a regular shape, like a cylindrical shape with a certain diameter. The turning of the workpiece may create one or more cylindrical surfaces of such a workpiece, wherein the one or more cylindrical surfaces have a reduced diameter. Generally, any revolution shape is feasible. The turning may also create one or more surfaces oriented primarily perpendicular to the workpiece axis, which may be referred to as facing by turning. The turning may also create one or more grooves in the outer surface of the workpiece, i.e. grooves circumferential with respect to the workpiece diameter, which may be referred to as grooving by turning. The turning may also create one or more groves in an end surface of the workpiece, i.e., grooves around the axis of rotation, which may be referred to as boring. The workpiece may also have an irregular shape, e.g. with a steplessly varying radius along the axis of rotation, or with a helix shape. A raw workpiece of an irregular shape may be pre-processed into a workpiece having a more regular shape, e.g., by facetting as described further below.
In an implementation of the method, the fluid-jet guided laser beam is provided perpendicular onto the machined surface, or tangential to the machined surface, or substantially tangential to the machined surface.
Accordingly, different orientations between the laser beam and the machined surface are possible, which enables different application scenarios. For example, the perpendicular orientation may result in a higher material removal rate and may thus be beneficial for machining larger workpieces, while the tangential orientation may allow higher precision, higher surface quality and less stress in the workpiece. The tangential case may comprise that a nozzle axis (of a fluid-generation nozzle for generating the fluid jet in the apparatus, wherein the nozzle axis is aligned with a propagation direction of the fluid jet) touches the machined surface of the workpiece. Notably, any angle between the laser beam and the machined surface may be achieved, if a 6-axes apparatus is used.
In an implementation of the method, the axis of rotation is perpendicular to a propagation direction of the fluid-jet guided laser beam as provided by the apparatus.
In an implementation of the method, the propagation direction of the fluid-jet guided laser beam does not intersect the axis of rotation.
For example, the propagation direction of the fluid-jet guided laser beam is perpendicular to the axis of rotation, but is offset from the axis of rotation. That is, a shortest connection between the axis of rotation and the machined surface is oblique to the propagation direction of the fluid-jet guided laser beam, e.g., also oblique to the vertical direction.
In an implementation of the method, the fluid-jet guided laser beam is provided at an angle onto the machined surface.
This angle is, for example, between 90° (in which case the fluid-jet guided laser beam would be provided perpendicular onto the machined surface) and 0° (in which case the fluid-jet guided laser beam would be provided tangential to the machined surface).
When the workpiece is processed with the fluid-jet guided laser beam according to the method of the first aspect, the radius of the workpiece decreases for the above implementations. Consequently, the angle at which the fluid-jet guided laser beam is provided onto the machined surface decreases as well, until the fluid-jet guided laser beam is provided tangential to the machined surface. An advantage of this is, that the machining of the workpiece changes automatically from a rougher process with a high material removal rate (MRR) from the machined surface to a smoother process that provided a surface finishing to the machined surface.
Moreover, when the fluid-jet guided laser beam is moved along a given profile, the offset of its propagation direction to the axis of rotation may change, and therefore also the angle at which the fluid-jet guided laser beam is provided onto the machined surface may change. For example, when the propagation direction of the fluid-jet guided laser beam is closer to the axis of rotation, said angle is higher (it approaches 90°), which leads to a higher throughput and MRR. The quantity of material removed may accordingly increase as the profile path leads the fluid-jet guided laser beam closer to the axis of rotation. Thus, with the method of the first aspect a functional machining strategy may be applied, which provides high throughput to an area requiring large volume of material to remove, while finishing an area closer to the workpiece outer diameter in a smooth manner, without any parameter variation.
In an implementation, the method further comprises moving the fluid-jet guided laser beam along a movement direction during turning the workpiece.
Accordingly, the laser beam may move along a determined path on the workpiece surface, for instance, it may describe a helix path. Different shapes of the turned workpiece can thus be realized. In particular, the laser beam may be moved by relatively displacing the workpiece and the laser beam against one another. That means, also the workpiece may be moved, or the workpiece and the laser beam may be moved, to realize the effective movement of the laser beam. It may be possible to linearly displace the laser beam and/or the workpiece along two or three axes at the same time or subsequently. Further, it may be possible to rotate the workpiece around two or three different axes of rotation during the machining. A rotation of the workpiece around one or more axes of rotation may be synchronized with a linear displacement of the workpiece and/or the laser beam along one or more axes.
The fluid jet may accordingly move over the workpiece. In an embodiment, the fluid jet may perform a multi-pass motion over the workpiece. The multi-pass motion may be (predominantly) effected by the rotation of the workpiece.
In an implementation of the method, the movement direction is parallel or perpendicular to the axis of rotation, and is perpendicular to the propagation direction of the fluid-jet guided laser beam.
In an implementation of the method, the axis of rotation is parallel to the fluid-jet guided laser beam.
In an implementation of the method, the laser beam is pulsed; and a rotational speed of rotating the workpiece around the axis of rotation is set such that consecutive pulses of the pulsed laser beam overlap each other by at least 50% on the machined surface of the workpiece.
That means, the laser beam may describe a continuous path on the machined surface of the workpiece. The 50% or more overlap of the laser pulses result in an efficient machining of the workpiece, and particularly in a low surface roughness of the machined surface of the machined workpiece.
In an implementation of the method, the laser beam is pulsed, and the pulsed laser beam comprises at least two superimposed pulsations selected based on the particular material of the workpiece, wherein a first pulsation has a different power and frequency than a second pulsation.
In other words, for a single material of the workpiece, which is to be machined using the method of the first aspect, at least two pulsations may be selected and combined to form a complex pulsed laser beam. Each laser pulsation contributes a certain, particularly regular, pulse shape to the complex pulsed laser beam—i.e. at least a first laser pulse shape with a first laser power and first laser frequency and a second laser pulse shape with a second laser power and second laser frequency. The two laser powers and laser frequency superimpose. Thus, the complex pulsed laser beam may show a beating pattern.
Primarily, this method may be designated for machining a workpiece that is made of a solid block of one type of material (i.e., the particular material) and that uses the at least two pulsations for machining this particular material by turning. However, the method can also be applied to a workpiece including more than one material, e.g., a workpiece that is made of layers of different materials. In this case, each layer is ideally machined individually by using at least two pulsations per layer. If two such layers are to be machined at the same time, then preferably multiple pulsations are selected, particularly at least two pulsations per layer.
A first pulsation in the pulsed laser beam may be created by a dominant/master laser emission, e.g., output by a first laser source, and a second pulsation may be created by a slave laser emission, e.g., output by a second laser source. Each laser source may be configured to output a simple pulsed laser beam with a determined power (absolute peak power and/or pulse width) and frequency (pulse repetition rate). For example, the dominant/master laser emission may be selected such that the particular material to be machined shows a stronger absorption of that laser light and/or that it is of higher intensity than the slave laser emission, while the slave laser emission is selected such that the particular material shows a weaker absorption of that laser light and/or that it is of lower intensity than the dominant laser emission. However, the effects associated with the master/slave laser emissions described here are not necessarily defined in this document according to the naming “first” and “second” pulsation. The selection of power and frequency of each laser pulsation may thus be based (depend) on a frequency-dependent absorption coefficient of the particular material to be machined. In other words, the particular material may absorb differently at different laser emission wavelengths and pulse characteristics. Notably, two superimposed laser pulsations may also be created by a single, dedicated laser source.
The complex pulsed laser beam can be composed such that it creates an ablation of workpiece material, which leaves the surface of ablation very homogeneous. In particular, by selecting the at least two pulsations in dependence of the particular workpiece material, a very low surface roughness and few or even no surface quality changes can be achieved. Furthermore, the occurrence of defects and chippings can be significantly reduced or even suppressed completely. Thus, the machining of workpieces, particularly of workpieces made of hard and/or brittle material, is improved.
In an implementation of the method, the first pulsation is suitable to cut the particular material of the workpiece; and the second pulsation is not suitable to cut the particular material of the workpiece and/or is suitable to smooth a surface of the particular material of the workpiece, for instance, to smooth a surface created by cutting the particular material with the first pulsation.
This means that the first pulsation in the pulsed laser beam (e.g., the dominant laser emission) taken alone would already cut/ablate the workpiece material, but with a relatively bad surface quality. The second pulsation (second pulsed laser emission) taken alone would not be able to cut/ablate the workpiece material, but may only be able to smooth or polish a surface of the workpiece. These abilities of the two laser pulsations are due to their specific characteristics, in particular, due to their respective power and frequency. These characteristics are selected based on the type of material of the workpiece that is to be machined. The at least two laser pulsations, when superimposed in the pulsed laser beam used by the method of the first aspect, work together to machine the workpiece with an improved surface quality. This may lead to a considerably lower surface roughness. Additionally, defects and material chipping can largely be avoided.
In an implementation, the method further comprises facetting the workpiece, before turning the workpiece; wherein facetting the workpiece comprises cutting off a set of pieces from the workpiece with the fluid-jet guided laser beam, to reduce a diameter of the workpiece with respect to the axis of rotation.
The facetting may help to quickly reduce the size of larger workpieces, in order to speed up the overall process of machining the workpiece including the turning. The facetting may particularly reduce a diameter of the workpiece, while enabling the subsequent turning process to be carried out efficiently and with high precision.
Notably, a diameter of the workpiece may vary along the workpiece (e.g., along the main axis of rotation for turning). One may cut such a workpiece to a controlled shape by performing the facetting before the turning, thus allowing better turning results afterwards. Further, the facetting may allow obtaining various shapes of the machined workpiece, for instance, shapes including spheres or half-spheres.
In an implementation, of the method, cutting off a piece from the workpiece comprises: cutting into the workpiece with the fluid-jet guided laser beam; rotating the workpiece by a certain angle around the axis of rotation; and cutting again into the workpiece with the fluid-jet guided laser beam, to cut out the piece from the workpiece.
The first cutting into the workpiece may comprise cutting partially into the workpiece thickness. Notably, one or more pieces of the workpiece could each also be cut out/off from the workpiece with one cut, instead to two cuts with rotating the workpiece in between the two cuts.
In an implementation of the method, facetting the workpiece comprises: cutting off a first subset of pieces from the workpiece, wherein the certain angle is a larger angle, to reduce the diameter of the workpiece with respect to the axis of rotation; and cutting off a second subset of pieces from the workpiece, wherein the certain angle is a smaller angle, to further reduce the diameter of the workpiece with respect to the axis of rotation.
In this way, facetting with the larger angle provide a rough workpiece shape, but a fast facetting process, while the subsequent facetting with the smaller angle allows reducing the workpiece shape to be smoother. Overall this results in a reduction of the process time.
In an implementation of the method, the method further comprises performing an optimization algorithm based on a size and/or a shape of the workpiece and regarding to a surface finish of the machined workpiece and/or a process time of machining the workpiece; and performing the facetting and the turning of the workpiece based on a result of the optimization algorithm.
The algorithm may select the facetting strategy, i.e., how to facet the workpiece. Constraints taken into account by the algorithm may comprise a maximum diameter or volume of the workpiece (typically, before facetting) and a minimum diameter or volume of the workpiece (typically, as desired after the subsequent turning). The algorithm may particularly determine at least one of: how many pieces to cut off from the workpiece, how many facets to create, what certain angle to use in the facetting, whether to cut off a first subset of pieces and a second subset of pieces as described above, a difference between the first and the second certain angle, from which side to cut into the workpiece (e.g., determined for each cut), what laser power to use per each cut, how far and fast to turn the workpiece after the facetting.
In an implementation of the method, a material of the workpiece comprises at least one of: diamond; a diamond composite; polycrystalline diamond; polycrystalline boron nitride; silicon carbide; a super-alloy; a ceramic; PHYNOX; titanium; a titanium alloy; a cobalt alloy; composite materials containing the previously mentioned materials.
Accordingly, workpieces of many kinds of materials can be turned, even (very) hard materials and (very) brittle or heat sensitive materials, or compliant and/or soft materials.
In an implementation, the method further comprises, in addition to turning the workpiece, at least one of: straight deep cutting into the workpiece, drilling the workpiece, engraving the workpiece, and laser milling the workpiece, with the fluid-jet guided laser beam.
In an implementation of the method, the method is performed automatically and/or seamlessly by the apparatus; and/or the method is performed by the apparatus in a single process.
In an implementation of the method, an arithmetic average roughness of the machined surface of the machined workpiece is 0.4 μm or less.
In particular, the arithmetic average roughness may be 0.2 μm or less. In an implementation of the method, a diameter of the workpiece is larger than 30 mm. For instance, the diameter of the workpiece may be 125 mm or larger.
Accordingly, it is well feasible to perform turning also on larger workpieces (larger diameter and/or volume) with the method of the first aspect, especially in the case of tangential incidence, compared to turning with a laser without a fluid jet. Notably, a workpiece may have the regular shape of a cylinder, or of a sphere, or the like, for instance, having a constant and well defined diameter. However, a workpiece may also have an irregular shape and/or a diameter varying along an axis of turning. The diameter in this case may refer to the largest diameter measurable for the workpiece. The diameter may measure a distance from one workpiece surface (e.g., the machined surface) to the opposite workpiece surface. A diameter of a workpiece may be as commonly understood by the skilled person in this technical field.
A second aspect provides an apparatus for machining a workpiece, the apparatus comprising: a machining unit configured to provide a fluid-jet guided laser beam; a holder configured to hold and rotate the workpiece; and a control unit configured to control the machining unit and the holder, respectively, to turn the workpiece and for turning the workpiece to: rotate the workpiece around an axis of rotation during the machining; and provide the fluid-jet guided laser beam to a machined surface of the workpiece.
In an implementation of the apparatus, the apparatus is configured to rotate the holder to rotate the workpiece around two or three different axes of rotation, and to linearly displace the workpiece along two or three axes; and/or the control unit is configured to control the holder to synchronize a rotation of the workpiece around one or more axes of rotation with a linear displacement of the workpiece along one or more axes.
The apparatus of the second aspect provide all advantages described above for the method of the first aspect, and can be implemented likewise. That is, in implementation forms of the apparatus, the apparatus may be configured according to the implementation forms of the method described above.
The apparatus particularly allows machining a workpiece, including turning the workpiece and optionally comprising further processing the workpiece, seamlessly and/or automatically and/or in a single process.
A third aspect provides a computer program comprising a program code either for controlling the apparatus according to the second aspect when being performed by a processor, in particular a processor of the control unit, or for performing the method according to the first aspect.
A fourth aspect of the present disclosure provides a non-transitory storage medium storing executable program code which, when executed by a processor, causes the method according to the first aspect or any implementation thereof to be performed.
The above-described aspects and implementations defining general embodiments according to the invention are explained in the following description of specific embodiments in relation to the enclosed drawings, in which
The method 20 is carried out by an apparatus 10 according to an embodiment of the invention, as is also illustrated schematically in
A material of the workpiece 30 may comprise at least one of: diamond, a diamond composite, polycrystalline diamond, polycrystalline boron nitride, silicon carbide, a super-alloy, a ceramic, PHYNOX, MAGIC GOLD, titanium, a titanium alloy, a cobalt alloy, one or more composite materials containing the previously mentioned materials. The workpiece 30 may have any volume or diameter. In particular, the workpiece may have a diameter that is larger than 20 mm, larger than 30 mm, or even larger than 50 mm, or even larger than 100 mm, or even larger than 125 mm.
The method 20 comprises turning 21, 22 the workpiece 30. The turning 21, 22 of the workpiece 30 comprises a step of rotating 21 the workpiece 30 around an axis of rotation 31 during the machining. The workpiece 30 may be rotated continuously around the axis of rotation 31 during the turning 21, 22 of the workpiece 30. The workpiece 30 may additionally be rotated around one or more further axes of rotation during the turning 21, 22 or more generally the machining of the workpiece 30. Further, the turning 21, 22 comprises a step of providing 22 the fluid-jet 11 guided laser beam 12 to a machined surface 32 of the workpiece 30. The fluid-jet 11 guided laser beam 12 may, for example, be provided perpendicular onto the machined surface 32 (as it is exemplarily shown in
In
A power of the laser beam 12, or a pulse characteristic of the pulsed laser beam 12 (i.e., a pulse width, a pulse rate, a pulse burst-rate, a pulse power, etc.) may be different for the machining, specifically the turning 21, 22, in the first case, in which the laser beam 12 is provided perpendicular onto the machined surface 32, and in the second case, in which the laser beam 12 is provided tangential to the machined surface 32. The first case may be beneficial for turning 21, 22 a larger workpiece 30 (e.g., with a large volume and/or diameter of e.g. 30 mm or more), since the perpendicular laser beam 12 may result in a higher workpiece material removal rate. The second case may be beneficial for turning 21, 22 workpieces 30 when requiring an improved precision and workpiece surface and when reduced stress in the workpiece 30 is necessary during the machining. Notably, the second case, in which the laser beam 12 is provided tangential to the machined surface 32, is only feasible due to the fact that the laser beam 12 is guided in the fluid jet 11. Such an orientation is not well feasible for a laser beam without fluid jet, because such a laser does not provide a long parallel focus, nor a sufficient coupling of laser power towards the workpiece surface.
In particular,
It is noted that for the machining of the workpiece 30, the movement directions shown in
In each case (a), (b), (c) shown in
A technical effect of the above is that the turning can be performed effectively and in a simple manner by guiding the fluid-jet 11 guided laser beam 12 along a single unchanged profile path 70 perpendicular to the axis of rotation 31, while rotating (turning) the workpiece 30. The transition between roughing and finishing can be performed automatically, with a locally selfoptimized ablation at every position along the axis of rotation 31. After a certain time of machining the workpiece 30, when the target radius is approached, the machining quality may be better at the places where the diameter is largest along the axis of rotation 31. These surfaces may advantageously correspond to the functional surfaces of the machined workpiece 30, i.e., of the final product.
The facetting 24 of the workpiece 30 may comprises cutting off a set of pieces from the workpiece 30 using the fluid-jet 11 guided laser beam 12, for instance, in order to reduce a diameter of the workpiece 30 (wherein the diameter is perpendicular to the axis of rotation 31). In particular, the facetting 24 may include a step of cutting 81 into the workpiece 30 with the fluid-jet 11 guided laser beam 12, further a subsequent step of rotating 82 the workpiece 30 by a certain angle around the axis of rotation 31, and further another step of cutting again 83 into the workpiece 30 with the fluid-jet guided 11 laser beam 12, in order to cut out a piece from the workpiece 30. In this way, multiple pieces may be cut out from the workpiece 30.
As further shown in
The facetting strategy for the workpiece 30 to be machined by the method 20 can be determined by an algorithm. For example, an optimization algorithm may be performed, for example, based on a size (e.g., a volume and/or diameter) and/or a shape of the workpiece 30, and/or regarding to a surface finish of the machined workpiece 30, and/or based on a process time of machining the workpiece 30. Then, the facetting 24 (and also the subsequent turning 21, 22) of the workpiece can be performed based on a result of the optimization algorithm. The result may comprise the cutting lines 90, particularly a sequence of cuts represented by such cutting lines 90.
In an example, a constraint for determining the best facetting strategy of the workpiece may be a maximum radius (e.g., the starting radius or diameter of the workpiece 30, i.e. before facetting 24), and a minimum radius (e.g., the desired final radius or diameter of the workpiece 30 after facetting 24). A further constraint may be a minimum defects size post process for the workpiece 30. An algorithm for determining the facetting strategy for the workpiece 30 may then provide, as an output result, a number of facets that the workpiece 30 should have after the facetting 24 and/or a most efficient processing order of cutting off pieces from the workpiece 30, i.e. of cutting facets into the workpiece 30. Further, for the facetting 24, a maximum volume of material to be reduced, and a maximum length of each cut may be taken into account by the algorithm. The final shape of the workpiece 30 may notably be a polygon, e.g., with an offset with true geometry. The algorithm may be performed by the apparatus 10, and the apparatus 10 may directly use the results of the algorithm to perform the facetting 24 and then the turning, for example, in one run.
The turning 21, 22, with or without facetting 24, may be combined with one or more further process steps, for instance, with at least one process step comprising straight deep cutting into the workpiece 30, drilling the workpiece 30, engraving the workpiece number 30, and laser milling the workpiece 30, with the fluid jet 11 guided laser beam 12. The apparatus 10 may, in addition to the facetting 24 and turning 21, 22, may also carry out the further process steps.
In all embodiments, the method 20 may be performed automatically, and/or seamlessly, and/or in a single process, by the apparatus 10 described in the following with respect to
The machining unit 101 is configured to provide a laser beam 12 coupled into a pressurized fluid jet 11. The control unit 103 is configured to control the machining unit 101 and the holder 102. In particular, the control unit 103 may control the holder 102 to rotate 21 the workpiece 30 around an axis of rotation 31. Further, the control unit 103 may control the machining unit 101 to provide 22 the fluid-jet 11 guided laser beam 12 to a machined surface 32 of the workpiece 30, particularly while the workpiece 30 is rotated 21. These actions may implement the method 20 according to an embodiment of the invention as shown in
The optional optical sensor 103a may be configured to determine, during the machining of the workpiece 30, a state of machining the workpiece 30. For instance, it may determine whether the laser beam 12 has broken through the workpiece 30, or is about to break through the workpiece or has not broken through the workpiece 30 (for instance, in case that a piece of the workpiece is cut out during the facetting 24). In this case, the current machining step can be immediately stopped and the apparatus 10 can move on to the next machining step. The distance sensor 103b may be configured to measure a distance between the machining unit 101 and the machined surface 32 of the workpiece 30, for instance, during the turning 21, 22. The apparatus 10 may thus determine how much material has been removed from the workpiece during the turning 21, 22. The distance sensor 103b may be further configured to measure a surface orientation of the machined surface 32 of the workpiece 30. The control unit 103 may then, for instance, determine how to provide the fluid-jet 11 guided laser beam 12 onto the machined surface 32 based on the measured surface orientation, in order to enable the most efficient turning 21, 22 of the workpiece 30.
The machining unit 101 may couple the laser beam 12—e.g., as received from a laser source 105, which may optionally be a part of the apparatus 10, or e.g. from multiple laser sources 105—into the fluid jet 11. This coupling may be done in the machining unit 101. The machining unit 101 may particularly include an optical element, like at least one lens 106, for coupling the laser beam 12 into the fluid jet 11. The laser beam 12 may be produced outside of the machining unit 101, and may be injected into the machining unit 101. In the machining unit 101, a mirror, and/or a beam splitter 107, and/or another optical element, may guide the laser beam 12 towards e.g. the at least one lens 106. The beam splitter 107 may also be used to couple part of the laser light, or electromagnetic radiation coming from the workpiece 30, to the optical sensor 103a. The machining unit 101 may also include an optically transparent protection window 109, in order to separate the optical arrangement, here exemplarily the optical element 106, from the fluid circuitry (e.g., water circuitry), and from the region of the machining unit 101 where the fluid jet 11 is produced.
For producing the fluid jet 11, the machining unit 101 may include a fluid jet generation nozzle 108 having an aperture of a certain size. The fluid jet generation nozzle 108 may be disposed within the machining unit 101 to produce the fluid jet 11 in a protected environment. The aperture may define the width of the fluid jet 11. The aperture may have, for example, a diameter of 10-200 μm, and the fluid jet 11 may have, for example, a diameter of about 0.6-1 times the aperture diameter. The pressure for the pressurized fluid jet 11 may be provided via an external fluid supply 104, which is typically not part of the apparatus 10 (but can be). For instance, the pressure is between 50-800 bar. For outputting the fluid jet 11 from the apparatus 10, the machining unit 101 may include an exit nozzle with an exit aperture. The exit aperture is particularly wider than the fluid nozzle aperture.
The control unit 103 may further control the at least one laser source 105 (e.g., it may command a laser controller of the laser source 105). That is, the control unit 103 may instruct a laser controller of the laser source 105 to output an according laser emission. The laser controller of the laser source 105 may thereby be able to set a constant or pulsed laser beam, for the latter particularly to set a pulse power, pulse width, pulse repetition rate, pulse burst rate, or a pause between pulses according to the instructions of the control unit. For instance, for the turning 21, 22, pulse intensity of the laser beam 12 may in a range of 0.4-2 GW/cm2, and/or an average power of the laser beam 12 may be in a range of 20-300 W, and a pulse length of the laser beam 12 may be in a range of 150-400 ns. The control unit 103 may also control the fluid supply 104.
During the turning 21, 22, the workpiece 30 may be held by the holder 102. The apparatus can be arranged such that it is able to machine the workpiece 30 held by the holder 102. The holder 102 may be attached to a rotatable element of the apparatus 10, or may itself be rotatable element of the apparatus 10. The apparatus 10, in particular the control unit 103, may thereby control movements of the holder 102 in up to three dimensions (e.g. in x-y-z as indicated in
The rotation of the holder 102 may be driven by a motor or CNC. For instance, the holder 102 may comprise a rod or a so-called “Dop”. The holder 102 may be at least 10% smaller, particularly at least 20% smaller (in diameter/width), than the workpiece 30 diameter. The holder 102 may rotate around the axis of rotation 31 (indicated in
The optical sensor 103a may be arranged to receive a laser-induced electromagnetic radiation that propagates away from the workpiece 30 (e.g., while cutting the workpiece 3011 with the laser beam 12), e.g., through the fluid jet 11 and further through at least one optical element 106, 107 towards the optical sensor 103a. The optical sensor 103a may in particular be arranged to receive the laser-induced electromagnetic radiation through the fluid jet 11 and through the at least one optical element 106, which is configured to couple the laser beam 12 into the fluid jet 11. The laser-induced electromagnetic radiation may include secondary radiation emitted from a portion of the workpiece 30 that is cut with the laser beam 12. For instance, the laser-induced electromagnetic radiation may be induced, because the machined surface 32 of the workpiece 30 is transformed into a plasma. This plasma may emit a characteristic radiation, which can be easily isolated on or by the optical sensor 103a. The laser-induced electromagnetic radiation may also include primary laser radiation that is reflected from the workpiece 30. The laser-induced electromagnetic radiation may also include secondary radiation generated by scattering, preferably Raman scattering, of the laser beam 12 in the fluid jet 11.
The distance sensor 103b may be a second optical sensor (i.e., in addition to the optical sensor 103a) or an ultrasound sensor. In this case, the distance sensor 103b may be arranged to measure optically the distance to the workpiece surface and/or the surface orientation of the workpiece 30, e.g., by measuring light reflected from the workpiece 30. To this end, the distance sensor 103b may also be configured to send light onto the workpiece 30. The distance sensor 103b may also be a touch probe. In this case, it may be arranged such that it can touch the workpiece 30 for performing the surface orientation measurement, or may be configured such that it can move or be moved towards the workpiece 30 to perform the measurement.
The optical sensor 103a and/or the distance sensor 103b may be arranged in the machining unit 101. However, the optical sensor 103a may also be arranged in the laser source 105. In this case, laser-induced radiation may back-propagate from the workpiece 30, and may be guided through the machining unit 101 to the laser source 105, where it is received by the optical sensor 103a. The machining unit 101 can be optically connected to the laser source 105, for instance, by an optical fiber.
Further, the optical sensor 103a may be configured to convert the received radiation into a signal. The control unit 103 may include processing circuitry, which is configured to determine a state of machining/cutting the product 11 based on the signal. The state of machining the workpiece 30 may be, whether the laser beam 12 has broken through the workpiece 30.
The apparatus 10, in particular the control unit 103, may comprise a processor or processing circuitry (not shown) configured to perform, conduct or initiate the various operations of the apparatus 10 described in this disclosure, in particular to perform the method 20. The processing circuitry may comprise hardware and/or the processing circuitry may be controlled by software. The hardware may comprise analog circuitry or digital circuitry, or both analog and digital circuitry. The digital circuitry may comprise components such as application-specific integrated circuits (ASICs), field-programmable arrays (FPGAs), digital signal processors (DSPs), or multipurpose processors.
The apparatus 10 may further comprise memory circuitry, which stores one or more instruction(s) that can be executed by the processor or by the processing circuitry, in particular under control of the software. For instance, the memory circuitry may comprise a non-transitory storage medium storing executable software code or program code, which, when executed by the processor or the processing circuitry, causes the various operations of the apparatus described in this disclosure, in particular causes the method 20 to be performed.
The present disclosure has been described in conjunction with various embodiments as examples as well as implementation forms. However, other variations can be understood and effected by those persons skilled in the art and practicing the claimed embodiments, from the studies of the drawings, the description and the independent claims. In the claims as well as in the description the word “comprising” does not exclude other elements or steps and the indefinite article “a” or “an” does not exclude a plurality. A single element or other unit may fulfill the functions of several entities or items recited in the claims. The mere fact that certain measures are recited in the mutual different dependent claims does not indicate that a combination of these measures cannot be used in an advantageous implementation.
The embodiments of the invention have various application scenarios. For instance, the method 20 may be beneficial in the manufacturing of watches, for instance, because of the low surface roughness achievable, or due to the fluid jet 11 verticality possible with the apparatus 10, or the versatility of the method 20. For instance, the method 20 may be performed to manufacture or shape pinions or cabochons. Further, the method 20 may be beneficial for manufacturing grinding tools or the like, which usually require hard materials. The benefits, for instance, come from the high material removal rate that is possible with the method 20, or the fluid-jet 11 verticality possible with the apparatus 10. Further, the method 20 may be beneficial for manufacturing or shaping medical ceramics. The benefits, for instance, come from the high material removal rate that is possible with the method 20, or the sensitive treatment by the fluid-jet guided laser beam 12, particularly in the tangential orientation, of (heat) sensitive and/or fragile materials.
Number | Date | Country | Kind |
---|---|---|---|
20205116.5 | Nov 2020 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2021/079968 | 10/28/2021 | WO |