WO2008104155A1 - Device and method for surface peening - Google Patents

Abstract

The invention relates to a method for surface peening, in particular for ultrasonic shot peening, of a component (20), in particular a gas turbine. According to said method, one part of the surface of the component (20) is hardened by exposure to blasting material. The component (20) is positioned in relation to a mask part (10), and at least one mask opening (16) associated with the mask part delimits the corresponding part of the surface of the component (20) that is to be blasted. The invention also relates to a device for carrying out said method.

Description

 Method and device for surface blasting

The invention relates to a method and a device for surface blasting, in particular for ultrasonic shot peening of a component, in particular a gas turbine, in the preambles of claims 1 and 14 specified type.

Such a method and such a device can already be seen, for example, from WO 93/20247 A1 as known. Among other things, the local method and the device there for ultrasonic shot peening of a plurality of teeth of a toothing comprehensive portion of the surface of a component is used. As a blasting serve metal balls, which can be accelerated by means of an ultrasonic sonotrode vibration device. The part of the toothing of the component to be radiated is delimited by a blasting chamber, which comprises corresponding slide walls.

A disadvantage of the known method and the known device, however, is the fact that, for example, the teeth of the toothing are exposed to different sub-areas of the surface different loads. Thus, for example, the respective tooth gap bottom and the respective pressure flank of the tooth is subjected to completely different loads than is the case, for example, in the case of the counter flank or the end face of the tooth. Due to its shape, moreover, the problem arises that, for example, the corner regions, radii or the like of a tooth of the toothing are optionally extremely difficult to solidify. Likewise, with the already known method and the device used therefor, an effective and load-compatible solidification of the respective partial area of the surface is not readily possible.

Object of the present invention is therefore to provide a method and an apparatus of the type mentioned, with which a more effective and load-fairer solidification of individual portions of the surface of the portion is possible. This object is achieved by a method and an apparatus having the features of claims 1 and 14, wherein it is the component to a toothed component, in particular a gear or pinion. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the respective dependent claims.

In order to enable a highly effective and load-adequate solidification of the respective, to radiating portion of the surface of the component, it is provided in the inventive method that the component is positioned relative to a mask part, by means of which at least one associated mask opening of the corresponding, to be irradiated portion the surface of the component is limited. In other words, it is provided according to the invention to at least partially limit a partial area of the surface of the partial area to be acted upon by a desired intensity or a specific abrasive material by arranging a corresponding mask section with an associated mask opening on the surface of the component. It is clear that in this case either either the component can be positioned on the stationary mask part or that the mask part - optionally including a vibration device and other components - is relatively positioned on the stationary component.

As a result of the delimitation of the respective subarea by means of the corresponding mask opening of the mask part, an extreme individual solidification of a corresponding subarea of the surface can thus take place, depending on which loads this surface area is exposed to. For example, it is thus conceivable to process the associated pressure flank or the corresponding tooth gap bottom differently in the case of a respective tooth of a toothing, than, for example, the corresponding counter flank or end face. Accordingly, the higher loaded pressure flank can be acted upon under other conditions or optionally with other blasting material, as is the case, for example, in the case of the less loaded counter flank of the tooth. Due to the limitation of the respectively to be machined portion of the surface of the component by means of the corresponding mask opening of the mask part can also be taken into account geometric particularities. Thus, it may be necessary, for example, that corner regions, radii or the like must be solidified in a different manner than is the case, for example, with flat or planar partial regions.

Overall, however, it can be seen that an individual radiation of individual partial areas of the surface of the component, in particular a toothing, is possible due to the mask part used. Optionally, thus higher surface near residual stresses can be achieved while avoiding softening effects by Herzsche pressing. As a result, there is an improved surface quality, wherein the respective portions are solidified according to stress or stress.

In a further embodiment of the invention, it has also proven to be advantageous if the mask part is positioned relatively between the component and a vibration device for accelerating the blasting material, wherein the at least one mask opening of the mask part is used as blasting chamber. As a result, the component can be positioned in a simple manner opposite relative to the vibration device, wherein the mask part or its mask opening arranged between the part region to be machined of the surface of the component and the vibration device limits the beam space accordingly.

As further advantageous, it has been shown that the mask part is used for surface blasting a portion of a toothing. In particular, in such gears, namely, the problem arises that different sub-areas are exposed to different loads. In addition, the individual teeth of the toothing usually have a complex geometry, so that it is possible with the now used each mask part, different sub-areas - for example, flat partial areas or corner areas with radii - to irradiate individually. As a result, with the mask part used according to the invention an individual Radiation result over different portions of each tooth can be achieved, so that overall results in a very stable and wear-resistant teeth.

In a further embodiment of the invention, it has also proven to be advantageous if at least one of the steel chamber formed by the mask opening of the mask part associated reflection element, in particular reflection sheet is used for surface blasting of the component. By means of such a reflection element or reflection sheet, it is also possible, for example, to effectively surface-blast subregions lying laterally of the blasting chamber, for example the end faces or tooth edges of the respective tooth, without damage.

For surface blasting of several subregions of the surface in succession, it is conceivable that the component is moved relative to the mask opening of the first part. Thus, it is conceivable, for example, to move the component stepwise with the respective subarea in registration with the mask opening in order to carry out the surface radiation. Likewise, however, it is also conceivable for a plurality of mask openings of one or more mask parts to be used for surface blasting of a plurality of subregions, so that a plurality of subregions of the surface can be blasted simultaneously. It will be appreciated that with such surface blasting, moving the component relative to the mask opening of the mask member need not be required.

Furthermore, it has proven to be advantageous if a blasting material is used for surface blasting, whose blasting particles have at least two different particle sizes and / or consist of at least two different materials. In other words, it is provided here to carry out the surface blasting with a blasting material, the blasting particles not only have a substantially uniform size or consist of a single material, but which have at least two different particle sizes and / or are made of different materials. Through the use of different particle sizes, it can be achieved, in particular, that the planar or planar partial areas of the surface of the component are blasted and solidified extremely homogeneously and uniformly by means of the larger jet particles be used while the beam particles with smaller particle size in particular serve that, for example, even corners with inner radii or the like can be solidified sufficiently well with a correspondingly small diameter. By a targeted blasting agent mixture with two preferably significantly different abrasive sizes or particle sizes is thus achieved that on the one hand with the large beam particles, the desired intensity and solidification is achieved and on the other with the small beam particles, the inner radii or corners of the possibly complex component completely can be solidified or blasted a beam.

If, in addition, beam particles of different materials are used, it is conceivable, for example, that the kinetic energy of the smaller beam particles is increased by a corresponding material with respect to the larger beam particles of higher density, so that a homogeneous intensity distribution, for example, in the inner radii or corners of the partial area the surface of the component can be guaranteed. In other words, by a suitable mixture of, for example, larger beam particles with relatively lower density and smaller Stralilteilchen with relatively higher density both over the flat or partial areas as well as over the corners or inner radii of the component, a homogeneous intensity distribution of the surface radiation and thus a uniform Solidification of the respective sub-area can be achieved.

Moreover, it can be advantageous if the blasting material consists of blasting balls which consist of at least two different diameters and / or of at least two different materials. By using blasting balls with a relatively uniform diameter, it is thus possible to ensure an extremely reproducible blasting result or uniform surface hardening of the respective subarea of the surface of the component.

In addition, it has proven to be advantageous if the particle size or the diameter of the at least one part of the blasting material - for example the smaller blasting particles or blasting balls - are adapted to the respective radii, corners or the like of the component. By such an adaptation of the respective jet particles or jet balls can thus be achieved that the radii, corners or the like are completely solidified.

The advantages described above in connection with the method according to the invention are equally valid for the device according to the invention for surface blasting. This is characterized in particular by a mask part which can be positioned relative to the component, by means of which mask opening the corresponding partial area of the surface to be radiated of the component is limited. Thus, an extremely simple device can be created by the mask part, in which the component is, for example, on the one hand a vibration device for accelerating the blasting material and on the other hand the mask part.

In this case, a particularly advantageous and simple device can also be created if a blasting chamber is formed by the mask opening within the mask part, in which the blasting material is preferably taken captive. Since the blasting chamber is preferably formed by the mask opening, which is present anyway, within the mask part, this results in a device of extremely simple construction, by means of which the respective subregion of the surface of the component is to be blasted.

It is clear that the device according to the invention - and in particular the mask part - could be arranged relative to a stationary arranged component. Conversely, it is of course also conceivable that the movable component is positioned on a stationary device, in particular a stationary mask part.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings; these show in:

1 is a schematic perspective view of a trained as rechteckförrnige plate mask part with an approximately quarter-circular ring-shaped recess in the region of a mask opening for surface blasting a korrespon- dierenden portion of a surface of a component is arranged, wherein the mask opening extends from the recess to the opposite side of the mask part continuously;

2 shows a schematic perspective view of the mask part according to FIG. 1, wherein a partially recognizable component is positioned relative to it with a spur toothing, which dips into the mask part in the region of the quarter-circle-annular recess, whereby a corresponding partial region of the toothing of the component coincides with the one in FIG Figure 1 recognizable mask opening is arranged, wherein the component is positioned by means of a partially recognizable holding device relative to the mask part;

Figure 3 is a schematic sectional view through the relative to the mask member positioned component, wherein on the side facing away from the component of the mask part in the region of the mask opening, a vibration device is positioned to act on blasting material, whereby by means of the mask opening a blasting chamber is formed which the discharge of blasting material essentially limited; and in

Figure 4 is a schematic sectional view through the device with the mask part and the vibration device for surface blasting of the component according to an alternative embodiment.

1 shows a schematic perspective view of a mask part 10 of a device for surface blasting, which is explained in more detail below, in particular for ultrasonic shot peening of a component (20, FIG. 2), in particular a gas trubline. The component is a gear or pinion, in particular for a transmission. The mask part 10 is designed here as a substantially rectangular metal plate. In an upper broad side 12, a recess 14 is introduced into the mask part 10, which - viewed in plan view - has an approximately quarter-circle annular basic contour. It can be seen that the recess 14 in a central or central area is introduced deeper into the mask part 10, as at the edge sides. Furthermore, a mask opening 16 can be seen in FIG. 1 in the central or deepest region of the recess 14, which is designed as a passage opening, as will be seen in more detail below in conjunction with FIG. 3 and FIG. As a result, the mask opening 16 exits on the broad side 12 opposite broad side 18 of the mask part 10 again.

In conjunction with FIG. 2, which shows the mask part 10 according to FIG. 1 in a schematic perspective view from another direction, it can be seen how a component 20 is positioned relative to the mask part 10. In the present case, the component 20 is designed as part of a gas turbine and essentially has an annular basic contour. In Figure 2, however, only about a quarter of this component 20 is shown. In conjunction with FIG. 1, the approximately quarter-circle-shaped contour of the recess 14 is explained in this case. Namely, it is adapted such that the component 20 dips approximately obliquely into the mask part 10 in the region of a quarter-circle ring, namely the recess 14. In other words, in the present case, an imaginary, unrecognizable central axis of the component 20 does not extend perpendicularly, but rather obliquely to the corresponding broad side 12 of the mask part 10. The component 20 is thereby attached to the device for surface blasting by means of a part 22 of an otherwise not further recognizable holding device 24 or held on the mask part 10. In other words, it is ensured by the part 22 of the holding device 24 that the annular component 20 is positioned correspondingly with respect to the mask part 10 or the mask opening 16.

The component 20 is presently provided on its dipping into the recess 14 of the mask part 10 end face with a toothing 26, which is only schematically seen in conjunction with Figure 3. Accordingly, the toothing 26 in the present case forms an end toothing of the component 20.

With reference to FIGS. 3 and 4, which show two alternative embodiments of the device for surface blasting of a respective component 20 in a schematic sectional view, the principle of operation or surface blasting is now explained. tert. First, the mask part 10 is shown in Figure 3 in a slightly different from Figure 1 embodiment, because the recess 14 in this case for the sake of simplicity not obliquely to the broad side 12, but rather is introduced perpendicular thereto. In the present case, the mask part 10 is arranged on a work table 28 of a corresponding processing machine, only two fastening strips 30 of which can be seen.

From a respective tooth 32 of the toothing 26 on the end face of the component 20, one of the two tooth flanks 34 can be seen, which extends between an associated tooth top side 36 and a respective tooth gap bottom 38. In this case, between the tooth flank 34 and the tooth gap bottom 38, there is an Innradius 40 which, in a manner which will be explained in more detail, is also to be solidified by means of surface blasting in addition to the tooth flank 34 or the tooth gap bottom 38. In the present case, two end faces 42, 44 of the respective tooth 32 extend approximately perpendicular to the tooth top side 36 or to the tooth flank 34.

It can further be seen from FIG. 3 that the component 20 or the toothing 26 protrudes into the recess 14 of the mask part 10 so far that the respective tooth top side 36 is assigned to the recess 14 approximately at the level of a corresponding lower surface 46 (FIG. In addition, it can be seen from FIG. 3 that, starting from this lower surface 46, the mask opening 16 is introduced into the mask part 10. In the present case, the width of the mask opening 16 is approximately matched to the width of the toothing or of the respective tooth 32. Of course, the mask opening may also have other contours or dimensions.

On the side of the mask part 10 opposite the component 20, in the present case a vibration device 48 is arranged, which in particular comprises an ultrasonic sonotor. By means of this vibration device 48, one of the mask opening 16 facing surface 50 to vibrate, so that by means of this a blasting material for surface blasting of the respective tooth 32 of the toothing 26 can be acted upon. In the present case, blasting balls 52, in particular high-strength steel balls, are used as blasting material. puts. Accordingly, if the surface 50 of the vibration device 48 is set in corresponding oscillations, then a corresponding partial region of the respective tooth 32 of the toothing 26 can be acted upon or solidified on the side of the mask opening 16 opposite the surface 50 of the vibration device 48.

It can be seen from FIGS. 1 and 3 that through the mask opening 16 there is a partial region-for example the respective one tooth flank 34 and the respective tooth gap bottom 38, or else the other tooth flank 34, the tooth top 36 or one of the end faces 42. 44 - surface blasted. In other words, the size of the mask opening 16 determines or limits a corresponding partial area on the surface of the component 20, which is to be correspondingly surface-blasted by means of the vibration device 48 arranged on the opposite side of the component 20.

It can be seen from FIG. 3 that the mask opening 16 within the mask part 10 essentially serves as a blasting chamber 54, so that the blasting balls 52 can not escape. The blasting chamber 54 may also be associated with reflection elements or reflecting plates, not shown, in order to guide the blasting balls 52 to a desired partial area, for example the end faces 42, 44 of the toothing 26. In addition, additional, movable limiting elements or boundary walls may be provided to prevent the escape of blasting material from the blasting chamber 54. This is the case in particular when the mask opening 16 in certain sections projects beyond the corresponding part of the component 20 to be radiated.

It can thus be seen from FIGS. 1 to 3 that certain subregions of the component 20 are released for surface blasting by the corresponding mask opening 16, while other subregions are correspondingly covered.

In order to achieve, for example, that of the toothing 26 and the respective tooth 32 both the corresponding desired tooth flank 34 - for example, the pressure flank - and the tooth gap bottom 38 as well as the inner radius 40 alike solid and homogeneously solidified, can be used in the present surface blasting beyond a blasting in the form of jet particles or blasting balls 52, which have at least two different particle sizes. In other words, within the blasting chamber 54 smaller and larger blasting balls 52 are arranged, which preferably have a considerably different particle size or a different diameter. The particle size or the diameter of the larger jet balls 52 may be, for example, in the range of about 1.0 mm to 4.0 mm, wherein these have in particular a size of about 1.2 mm to 1.8 mm. In a specific embodiment, the particle size or diameter of the larger blasting balls 52 is in the range of about 1.5 mm. If, as in the present case, the larger blasting balls 52 are made of a preferably higher-strength steel alloy, the result is a particularly advantageous and homogeneous hardening, in particular of the planar or planar partial areas of the surface of the component 20.

The small beam particles or jet balls 52, which may also be made of a high-strength steel alloy, for example, also have a particle size or a diameter in a range between 0.3 mm and 1.3 mm, in particular smaller jet balls 52 in a Range between 0.5 mm and 1.0 mm are used. In a specific embodiment, the particle size or diameter of the smaller jet balls 52 is about 0.8 mm. In particular, it can be achieved by the indicated regions of the smaller jet balls 52 that the corresponding smaller inner radii 40 or other corners can be solidified. In other words, the smaller jet balls 52 are adapted in their particle size to the respective inner radii 50 or the like so that they can be solidified accordingly. It is clear that for this purpose the particle size of the small beam particles 52 must be measured correspondingly smaller than or equal to the corresponding inner radius 40.

So that a homogeneous solidification can be realized both over the flat subareas of the surface of the component 20 as well as the corners or the respective Innenradius 40, the larger or smaller beam balls 52 are preferably made of different materials or they have a different density. In particular, you can the smaller blasting balls 52 have a higher density relative to the larger blasting balls 52, so that they have a higher kinetic energy after a corresponding acceleration by means of the vibration device 48 than the larger blasting balls 52. In this way it is achieved that both the flat and the angular sections the surface of the component 20 are uniformly or homogeneously solidified or that a homogeneous intensity distribution over the entire, each to be radiated portion can be realized.

In the embodiments of the device and the corresponding method shown in Figures 1 to 3, the component 20 is moved stepwise to bring the corresponding portions - for example, the respective tooth flank 34 and the associated tooth gap bottom 38 - in registration with the mask opening 16. In other words, the component 20 is moved to surface-blast a plurality of portions relative to the mask opening 16 of the mask member 10. In an alternative embodiment, however, it would also be conceivable for a plurality of partial areas of the surface of the component 20 to be surface-blasted simultaneously by using a plurality of mask openings 16 within one or more mask parts 10, which are positioned corresponding to one another. In this case, it would of course also be conceivable to provide one respective vibration device 48 per mask opening 16.

It can be seen that the illustrated device can be easily integrated into a production line, or, for example, in a deburring machine with a small footprint and inexpensive. In this case, a plurality of such devices can be arranged one behind the other in order, for example, first to irradiate one partial area of the component in each case, and then other partial areas in the other device. Likewise, it would then also be conceivable to detach and change the mask part 10 from the corresponding device in order, if appropriate, to delimit other partial areas with differently shaped mask openings 16.

The already mentioned reflection elements laterally in the respective blasting chamber 52 enable the effective blasting of, for example, the sand edges or the end faces 42, 44 without causing damage in this area. In other words, it can be ensured by the reflection elements in the respective blasting chamber 52 that the balls are guided centrally to the tooth edge or end face 42, 44 in order to avoid cracks at the transitions or edges. The process according to the invention enables high residual stresses close to the surface and the avoidance of softening effects due to Herz's pressure. By choosing the suitable subregion or the suitable blasting material, it is also possible that hand deburring, in particular of the tooth edges, can be dispensed with, since these are also rounded during surface blasting. Through the use of ultrasound irradiation, the respective tooth edges and the tooth gap bottom 38, as well as the tooth flanks 34, are solidified very effectively and the surface roughness is markedly increased, without unduly deforming the edges despite low rounding effort.

Finally, FIG. 4 shows an alternative embodiment of the device according to FIG. 3, again the component 20 being positioned relative to the stationary mask part 10 fastened to the work table 28.

Claims

claims 1. A method for surface blasting, in particular for ultrasonic shot peening, a component (20), in particular a gas turbine, in which a portion of the surface of the component (20) is solidified by exposure to blasting, characterized in that the component (20) relative to a mask part (10) is positioned, by means of which at least one associated mask opening (16) of the corresponding, to be irradiated portion of the surface of the component (20) is limited. 2. The method according to claim 1, characterized in that the mask part (10) is positioned relatively between the component (20) and a vibration device (48) for accelerating the blasting material, wherein the at least one mask opening (16) of the mask part (10) as Blasting chamber (54) is used. 3. The method according to claim 1 or 2, characterized in that by means of the at least one mask opening (16) of the mask part (10) of the partial region of a toothing (26) of the component (20) is limited. 4. The method according to claim 3, characterized in that by means of the at least one mask opening (16) of the mask part (10) each associated tooth gap bottom (38) and a respective associated pressure flank (34) of a tooth (32) of the toothing (26) limited becomes. 5. The method according to claim 3 or 4, characterized in that by means of the at least one mask opening (16) of the mask part (10) each associated counter-flank (34) and a respective associated end face (42, 44) of a tooth (32) of the toothing (26) is limited. 6. The method according to any one of claims 2 to 5, characterized in that for surface blasting of the component (20) at least one of the blasting chamber (54) associated refiektionsteil, in particular reflective sheet is used. 7. The method according to any one of the preceding claims, characterized in that for Oberfiächenstrahlen of several subregions of the surface successively the component (20) relative to the mask opening (16) of the mask part (10) is moved. 8. The method according to any one of the preceding claims, characterized in that for simultaneous Oberfiächenstrahlen of a plurality of subregions of the surface of the component (20) a plurality of mask opening (16) of one or more mask parts (10) are used. 9. The method according to any one of the preceding claims, characterized in that a blasting material is used, the beam particles (52) have at least two different particle sizes and / or consist of at least two different materials. 10. The method according to claim 9, characterized in that beam particles in the form of jet balls (52) are used with at least two different diameters and / or at least two different materials. 11. The method according to claim 9 or 10, characterized in that the particle size or the diameter of the at least one part of the used beam particles or jet balls (52) is adapted to respective radii (40), corners or the like of the component (20). 12. The method according to any one of claims 9 to 11 _5, characterized in that beam particles or jet balls (52) are used which have a different density. 13. The method according to any one of claims 9 to 12, characterized in that smaller beam particles or jet balls (52) are used, whose density is higher than that of the larger beam particles or jet balls (52). 14. Device for surface blasting, in particular for ultrasonic shot peening, of a component (20), in particular of a gas turbine, by means of which a partial region of the surface of the component (20) can be solidified by exposure to blasting material, characterized in that a mask part (10) is provided to which the component (20) is relatively positionable and which comprises at least one associated mask opening (16), with which the corresponding, to be irradiated portion of the surface of the component (20) can be limited. 15. The apparatus according to claim 14, characterized in that the mask part (10) relative to the component (20) and a vibration device (48) for accelerating the blasting material is positioned, wherein the at least one mask opening (16) of the mask part (10) as Blasting chamber (54) is used. 16. The apparatus of claim 14 or 15, characterized in that the blasting chamber (54) is assigned at least one reflection part, in particular reflection sheet. 17. Device according to one of claims 14 to 16, characterized in that by means of the at least one mask opening (16) of the mask part (10) of the partial region of a toothing (26) of the component (20) can be limited. 18. The device according to claim 17, characterized in that by means of the at least one mask opening (16) of the mask part (10) each associated tooth gap bottom (38) and a respective associated pressure flank (34) of a tooth (32) of the toothing (26) limited is. 19. The apparatus of claim 17 or 18, characterized in that by means of the at least one mask opening (16) of the mask part (10) each associated counter-flank (34) and a respective associated end face (42, 44) of a tooth (32) of the toothing (26) is limited. 20. Device according to one of claims 14 to 19, characterized in that a holding device (24) is provided, with which the component (20) relative to the mask opening (16) of the mask part (10) is movable for surface blasting of several subsections successively , 21. Device according to one of claims 14 to 20, characterized in that for the simultaneous surface blasting of a plurality of subregions of the surface of the component (20) one or more mask parts (10) are provided, each having one or more mask openings (16).