Patent Abstract:
Powder-delivery apparatus for delivering powdered cladding-material into the vicinity of a laser-beam spot includes a plurality of powder-delivery modules. Each of the modules is arranged to receive the cladding-material and deliver the cladding-material through a plurality of nozzles. The position of the nozzles in the modules with respect to the laser-beam spot is adjustable in three Cartesian axes. The modules are selectively removable from, and attachable to the apparatus. Nozzles in any one of the modules can be selectively prevented from delivering cladding-material.

Full Description:
PRIORITY CLAIM 
       [0001]    This application claims priority of U.S. Provisional Patent Application No. 61/441,107, filed Feb. 9, 2011, the complete disclosure of which is hereby incorporated by reference. 
     
    
     TECHNICAL FIELD OF THE INVENTION 
       [0002]    The present invention relates in general to apparatus for laser-assisted cladding (laser-cladding) of metal surfaces. The invention relates in particular to apparatus for delivering powdered cladding-material onto a surface in the presence of a high-power laser-beam. 
       DISCUSSION OF BACKGROUND ART 
       [0003]    Laser-cladding has been developed by the laser industry to solve a multitude of industrial applications. Laser-cladding involves directing a high power laser-beam, for example a beam having a total power of several kilowatts (kW) on to a surface to be clad while directing cladding-material in the form of powder into the laser-beam on the surface. The powder melts and hardens to form the cladding. Laser-cladding can be used to repair a worn surface using an identical material; build a layer of different properties onto a base material; or construct an entire near net-shape object directly from powder with specific properties. The powder can be delivered simply by gravity through a suitable nozzle, or entrained in a pressure-fed inert gas. The pressurized gas method lends itself to cladding in other attitudes than the horizontal plane and can even be used to generate three-dimensional shapes. 
         [0004]    A preferred laser-beam source is a two-dimensional array of diode-lasers made by stacking one directional arrays of diode-lasers known in the art as diode-laser bars. Such two dimensional arrays are commercially available with a total delivered power of over 1 kW. Several stacks may be used to provide extra power.  FIG. 1  schematically illustrates a modular laser-head assembly  10  arranged for projecting a laser-beam having a rectangular cross-section. Such a unit is available as a HighLight™ D-Series Unit, from Coherent Inc., of Santa Clara, California. Unit  10  includes a bar-stack module  12  which can hold two or more diode-laser bar stacks depending on power required. Attached to module  12  is a collimator optics module  14  including a plurality of inverse Galilean cylindrical lens pairs, arranged to collimate the output of the plurality of diode-laser bar stacks in module  12  in one axis (here the fast-axis) of the diode-laser bars. A condenser optics module  16  includes one or more elements arranged to project the one-axis collimated output into an elongated rectangular beam projection  18  on a working plane at a specified working distance from the condenser optics module. A surface to be clad would be placed in the working plane with provisions for relative motion between the surface and beam-projection  18  to deposit powdered cladding-material onto the surface. The slow-axis and fast-axis of the diode-laser bars are designated arbitrarily herein as the x-axis and y-axis respectively of a Cartesian set, with the beam propagation axis designated as the z-axis. 
         [0005]    In unit  10 , module  12  can be interchanged for a similar module having more or less diode-laser bar stacks for selecting, respectively, more or less total power. Inverse Galilean pairs in module  14  are cartridge-mounted and correspondingly interchangeable to adapt to a particular configuration of module  12 . Elements in module  16  are mounted on a sliding tray  20 , and accordingly are also interchangeable. This interchangeability of modules provides that laser-beam projection  18  can have a wide range of length and width to adapt to various cladding tasks. Powder delivery (cladding) apparatus can be attached to unit  10  via a flange  22  on module  16 . Only sufficient description of unit  10  is provided here for illustrating a laser-beam source which can be used with inventive cladding apparatus described herein. A detailed description of laser-head assembly  10  is provided in U.S. patent application Ser. No. 13/082,171, filed Apr. 7, 2011, assigned to the assignee of the present invention, and the complete disclosure of which is hereby incorporated herein by reference.  FIG. 2  schematically illustrates a prior-art powder-delivery (cladding-head) apparatus  30 , suitable for use with a laser-beam-source of which beam source  10  of  FIG. 1  is merely one particular example. Such a source is referred to hereinafter as a laser-head. Cladding-head  30  includes a mounting flange  32  having a fixed member  33  attachable to a corresponding flange on a laser head, for example, flange  20  of laser head  10  of  FIG. 1 . Flange  32  includes a movable member  34  attached to fixed member  33  and is adjustable in x and y with respect to member  32  by adjusting screws  38  and  40 . 
         [0006]    A four-sided hollow body  36 , open at both ends is suspended from movable member  34  of flange  32 . Attached to opposite sides of body  36  are powder-delivery plates  42 A and  42 B, seen in side-elevation in  FIG. 2 . Such plates typically include an internal manifold connection a plurality of channels terminating in a corresponding plurality of orifices at the delivery end of the plates. This detail is not shown in  FIG. 2  but is discussed in descriptions of embodiments of the present invention presented further hereinbelow. Powder from a reservoir thereof (not shown) is fed into plates  42 A and  42 B via fixtures  44 A and  44 B, respectively and delivered from the orifices into the vicinity of the laser-beam projection  18  in the working plane. In the drawing of  FIG. 2 , the delivery orifices of the delivery plates would be aligned parallel to the x-axis of the laser-beam. The powder is typically entrained in an inert delivery gas, such as nitrogen, at high pressure. The x-y position of the delivery orifices with respect to laser-beam projection  18  is adjustable by adjusting screws  38  or  40 . 
         [0007]    Controlled application of a suitable powder to a interaction point of the laser-beam with substrate material being clad is fundamental to laser-cladding technology. The powder must be precisely placed with respect to the laser energy and the substrate material in order for the process to be successful in producing a high quality, well bonded layer of the desired thickness and shape. The powder delivery nozzle (orifice) configuration has great impact on the clad deposit produced by the process. There are several different configurations of nozzles currently in use. The most common are: arrays of holes (or slots) in a plate for square or line shaped cladding, concentric cones with the powder ejecting from between the gap between the cones, or discrete nozzles singularly or in combination ejecting the powder simultaneously to the laser-beam interaction point for thin line clad deposition. 
         [0008]    In prior-art cladding apparatus the powder distribution shape in these configurations is not able to be changed without removing and replacing the emitting nozzle at best, or completely changing the cladding head at worst. Similarly, the overall size of the deposit is not currently capable of being physically adjusted at the nozzle output other than by injecting more or less powder into the delivery gas stream or using higher or lower delivery gas volume or pressure. Line-shaped clad deposits are desirable for depositing a large amount of material over a large area, be it on flat shapes or round shafts. Square-shaped claddings are desirable for building up thicker layers and controlling the net shape better; and circular shapes are desirable for producing thin lines for the greatest control in applying clad deposits over small features or making 3D near-net shapes. There is a need for a cladding-head that can accommodate the above-discussed variations. 
       SUMMARY OF THE INVENTION 
       [0009]    The present invention is directed to apparatus for delivering powdered cladding-material into the vicinity of a laser-beam spot defined by a laser-beam projected into a working plane. In one aspect, apparatus in accordance with the present invention comprises a hollow body through which the laser beam is projected onto the working plane. At least a first powder-delivery module removable attached to the hollow body and arranged to receive the powdered cladding-material to be delivered. The powder-delivery module includes one or more nozzles for delivering the received powdered cladding-material into the vicinity of the laser-beam projection in the working plane. The position of the one or more nozzles of the powder delivery module with respect to the laser-beam projection on the working plane is adjustable in x, y, and z Cartesian axes. 
         [0010]    In a preferred embodiment of the inventive apparatus, the powder-delivery module includes a plurality of nozzles for delivering the received powdered cladding-material. The powder delivery module further includes an arrangement for blocking a selected one or more of the nozzles such that only unblocked nozzles deliver the received powdered cladding-material. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0011]    The accompanying drawings, which are incorporated in and constitute a part of the specification, schematically illustrate a preferred embodiment of the present invention, and together with the general description given above and the detailed description of the preferred embodiment given below, serve to explain principles of the present invention. 
           [0012]      FIG. 1  schematically illustrates a prior-art laser head for producing a high power laser-beam suitable for laser-cladding. 
           [0013]      FIG. 2  schematically illustrates a prior-art cladding head for delivering powdered cladding-material into the vicinity of a laser-beam on a surface to be laser-clad. 
           [0014]      FIG. 3  schematically illustrates a preferred embodiment of a cladding head in accordance with the present invention including replaceable powder-delivery plates having an aligned plurality of powder-delivery nozzles with means to adjust the number of nozzles in the aligned plurality thereof through which powdered cladding-material is delivered. 
           [0015]      FIG. 3A  schematically illustrates detail of one configuration of the cladding-head of  FIG. 3  having two pairs of powder-delivery plates the plurality of nozzles in each pair thereof aligned parallel to each other, with nozzles in one pair aligned parallel to the x-axis and nozzles in the other pair aligned parallel to the y-axis of a laser-beam similar to that delivered by the laser-head of  FIG. 1 , with the number of nozzles in each plate through which powder is delivered being selectively adjustable. 
           [0016]      FIG. 3B  schematically illustrates detail of another configuration of the cladding-head of  FIG. 3  similar to the configuration of  FIG. 3A  but having only the x-axis aligned powder-delivery plates. 
           [0017]      FIG. 4A  and  FIG. 4B  schematically illustrates detail of a powder delivery plate in the cladding-head of  3 B including a manifold having adjustment plugs adjustable to selectively isolate powder delivery nozzles from a powder supply. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0018]    Continuing with reference to the drawings, wherein like components are designated by like reference numerals,  FIG. 3  schematically illustrates a preferred embodiment  50  of a laser-cladding-head in accordance with the present invention. Cladding-head  50  includes a flange  52  for attaching the cladding head to a laser-head similar to that of  FIG. 1 . 
         [0019]    An arrangement  56  is provided for providing x-y adjustment of the cladding head with respect to a laser-beam delivered by the laser-head and propagating through the laser head. A fixed member  58  of arrangement  56  is attached to flange  52  via a cylindrical extension  54 . A movable member  60  of arrangement  56  is movably attached to fixed member  58 . The x-position and y-position of member  56  with respect to member  58  are adjustable by knobs  62  and  64 , respectively. The relative x-y position of members  58  and  60  can be locked by a cam lever  57 . 
         [0020]    The x-y adjustment method described above is but one suitable mechanism for achieving the adjustment. Those skilled in the art will recognize that other mechanisms could be used without departing from the spirit and scope of the present invention. Such mechanisms include jacking screws, cams, sliding wedges, sliding shims or any mechanism capable of providing linear motion in either two axes independently or simultaneously. In addition the x-y locking mechanism could take any number of forms including locking screws, jacking screws with locknuts, locking clamps, locking wedges or other devices used to restrain motion between moving objects. 
         [0021]    A z-axis adjustment assembly  65  is attached to movable member  60  of the x-y adjustment via a threaded cylinder  68 A attached to the movable member. A complimentary threaded cylinder  68 B is attached to a mounting flange  74 . A rotatable threaded collar  70  connects cylinders  68 A and  68 B. Rotation of collar  70  is accomplished via an adjustment ring  64  having protruding pegs  66  to facilitate rotation of the collar as indicated by arrow A. Rotation of adjustment ring  64  translates into Z axis motion of the collar with respect to the sleeve, by moving cylinders  68 A and  68 B toward or away from each other, depending on the direction of rotation of collar  70 . The rotation position of the collar can be locked by a locking-ring  72 . Here again, this mechanism is only one of a number of possible mechanisms. 
         [0022]    Continuing with reference to  FIG. 3 , and with reference, in addition, to  FIG. 3A , a powder delivery assembly  76  is attached, via a flange  78  thereof, to flange  74  of the z-axis adjustment assembly. Powder-delivery assembly  76  includes a hollow four-sided body  79  to which are attached one pair of powder-delivery modules (plates)  80 A and  80 B, and another pair of powder-delivery modules  80 C and  80 D (module  80 D is not visible in  FIG. 3 ). Each powder-delivery module includes a plurality of nozzles  86  with orifices thereof arranged in-line. Cladding-powder from a source thereof (not shown) is fed into the modules entrained in an inert-gas under pressure via fixtures  82 A-D. A manifold within each module distributes the powder among the nozzles. Each, module here, also includes plugs  84 , which can be inserted or withdrawn, here, by screw-action, into or out of the manifold to select a number of nozzles through which powder can flow. This nozzle-selection process is described in detail further hereinbelow. 
         [0023]    In powder-delivery assembly  76 , lines of nozzles in modules  80 A and  80 B are parallel to each other and parallel to the x-axis of the laser-beam passing through the assembly via aperture  88  therein. Lines of nozzles in modules  80 C and  80 D are parallel to each other and parallel to the y-axis of the laser-beam. This arrangement is suitable for square-shaped claddings discussed above as being suitable for building up thick cladding-layers. The x-y adjustment assembly  56  and the z-axis adjustment assembly  65  provide that the nozzle positions of modules  80 A-D are, collectively, independently adjustable in three axes with respect to laser-beam spot  18  in the working plane. 
         [0024]      FIG. 3B  schematically illustrates another possible configuration  76 A of powder-delivery assembly  76 . Here modules  80 C and  80 D of  FIG. 3A  have been removed and replaced with passive blocking plates  94 . Plates  94  have downward-extending portions  96  thereof arranged to minimize migration of powder in the x-axis direction out of the laser-beam spot. This configuration of powder modules is for above-discussed line-shaped clad-deposits suitable for depositing a large amount of cladding-material over a large area. 
         [0025]      FIG. 4A  and  FIG. 4A  schematically illustrate details of plug-arrangements described above for limiting the amount of active nozzles in a powder delivery module  80 . The shape of the modules is depicted, here, in simplified form. Powder is injected via a conduit  88  into a manifold  90  from which nozzles  86  extend. In  FIG. 4A  plugs  84  are shown sufficiently withdrawn from manifold  90  such that all, here ten, nozzles can transmit the injected powder. In  FIG. 4B  plugs  80  are inserted into manifold  90  such that only a central four of nozzles  86  can transmit powder. The examples of  FIGS. 4A and 4B  are for symmetrical arrangement of active nozzles. Clearly with the manifold-plug mechanism depicted, asymmetrical arrangements are also possible. Other mechanisms are possible for selecting active nozzles. One very simple mechanism would be selectively disabling any nozzle by inserting a pin or the like in the delivery-end of the nozzle. This could be used for example to change the spacing between active nozzles. 
         [0026]    In summary the present invention is described above with reference to a preferred embodiment and certain specific examples. The invention, however, is not limited to this embodiment and examples. Rather, the invention is defined by the claims appended hereto.

Technology Classification (CPC): 1