Apparatus for additive manufacturing and use of the apparatus

Abstract

An apparatus for additive manufacturing includes a platform comprising a fixing device for fixing a component to the platform, wherein the platform is configured to vary an orientation of the component over an angle of at least 360° according to at least one spatial direction, and an actuation device for mechanically actuating the platform at a predefined frequency.

Claims

1. An apparatus for additive manufacturing, comprising: a platform comprising a fixing mechanism for fixing a component of a flow path of a gas turbine to the platform, wherein the platform is configured to vary an orientation of the component over an angle of at least 360° according to two orthogonal spatial directions while the component is fixed to the platform via the fixing mechanism, an actuation mechanism for mechanically actuating the platform to vary the orientation of the component wherein the actuation mechanism comprises a first vibration generator being configured for actuating a powdery base material at a first frequency and a second vibration generator being configured for actuating the powdery base material at a second frequency being different from the first frequency, wherein the first frequency is chosen from a first frequency range and the second frequency is chosen from a second frequency range and wherein the first frequency range and the second frequency range are disjunct, and a blocking mechanism being configured such that, during a variation of the orientation of the platform, the platform is engageable via a snap-mechanism for a blocking of the platform with respect to the actuation mechanism, and wherein the apparatus is configured such that, by the mechanical actuation of the platform, the powdery base material contained in a cavity of the component being fixed to the platform is removeable from the cavity.

2. The apparatus according to claim 1, wherein the actuation mechanism is driven by air pressure.

3. The apparatus according to claim 1, wherein the actuation mechanism is driven by piezoelectric and/or electromechanical mechanism, or an unbalanced motor.

4. The apparatus according to claim 1, wherein the first vibration generator and the second vibration generator are independently controllable.

5. The apparatus according to claim 1, wherein the fixing mechanism comprises a damping mechanism which is configured to prevent a transfer of vibrations from the component to the actuation mechanism.

6. A method for removing of a powdery base material from a cavity of an additively assembled component, comprising: using the apparatus according to claim 1 to remove the powdery base material by the mechanical actuation of the platform.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features, expediencies and advantageous refinements become apparent from the following description of the exemplary embodiment in connection with the Figures.

(2) FIG. 1 shows a schematic side view of an apparatus according to the present invention.

(3) FIG. 2 shows a schematic sectional view of a setup indicating a use of the apparatus of FIG. 1.

DETAILED DESCRIPTION OF INVENTION

(4) Like elements, elements of the same kind and identically acting elements may be provided with the same reference numerals in the Figures.

(5) FIG. 1 shows an apparatus 100. The apparatus 100 may be shaker or shaking table. The apparatus 100 advantageously relates to a tool or add-on for the additive manufacture of a component 10 or structure, advantageously by powder-bed based-techniques. In FIG. 1, a component 10 is particularly fixed to the apparatus 100.

(6) The component 10 is advantageously a component for an application in flow path hardware of turbo machines, such as gas turbine. The component 10 is advantageously manufactured from superalloys, such as nickel or cobalt-based superalloys for gas turbines.

(7) For fixing the component 10, the apparatus 100 comprises a platform 130 in turn comprising a fixing means 110. The fixing means 110 may be or comprise a fastener such as the bench vice, for fixing the component 10, advantageously after the structure 1 has been additively assembled or manufactured.

(8) The platform 130 may be or comprise a rotary table onto which the component 10 and/or structure 1 may be mounted, expediently by means of the described fixing means 110.

(9) The fixing means 110 may comprise at least two clamps as indicated in the Figures. Also, the fixing means 110 may comprise any expedient fixation features known to a skilled person, such as a clutch, grippers, an arbor or mandrel, screws, bolts, a caliper, or any other means suitable for fixing the component, advantageously according to a plurality of different spatial orientations.

(10) Further, the apparatus 100 comprises an actuation means 120, such as vibration or oscillatory means. The actuation means 120 is advantageously configured such that a structure or part of the component and/or the component 10 itself may be mechanically actuated, e.g. to a periodic actuation, such as a vibration or oscillation, at a predefined frequency range. Said frequency range advantageously encompasses a first frequency F1 or first frequency range and a second frequency F2 or second frequency range.

(11) The actuation means 120 may be driven by air pressure or comparable means. Additionally or alternatively, the actuation means may be driven by piezoelectrically and/or electromechanically, comprising the respective technical facilities known to a skilled person.

(12) FIG. 1 shows the apparatus 100 according to an orientation OR of the component 10.

(13) The platform 130 is advantageously configured such that the component—mounted to it—may be rotated around an axis Y (vertical axis in FIG. 1). Additionally, the platform 130 is advantageously configured such that the component 10 may as well be rotated or turned around an axis X (horizontal axis). Thus, the structure 1 and/or the component 10 may be rotated around two linearly independent axes of movement or rotation, advantageously over and an angle of 360° each. Accordingly, in theory, any excess base material may be removed from or shaken out of a cavity of the component, when the structure is shaken consecutively according to a plurality of different spatial orientations by the actuation means 120.

(14) The fixing means 110 expediently effects a fixation of the component 10 on or at e.g. the actuation means 120 and/or the apparatus 100. Therefore, the platform 130 may be provided with an angled suspension (not explicitly indicated). By a said suspension, the platform 130 is advantageously also rotatable around the spatial direction or axis X. Thus, the component 10 may be oriented upside down or according to any perceivable spatial orientation.

(15) The platform 130, as described, may further be adjustable by an electric or electromechanical drive, for example.

(16) The cavity 3 of the component 10 as shown in FIG. 1, is particularly shown at least partly filled with a base material 2, advantageously of a powdery and/or granular structure. The component 10 has advantageously been manufactured out of that base material 2, wherein the base material remaining in the cavity may be an excess base material, advantageously remaining from the manufacture, as may be usual in the additive fabrication of components by means of powder bed methods.

(17) The actuation means 120 is expediently provisioned for an actuation of or agitation of the platform 130 at a predefined frequency of frequency range, particularly for an effective removal of the base material, after the component has been manufactured. The removal of a powder or powdery base material from complex inner cavities of additively manufactured components poses a significant challenge, as access powder remaining or trapped in the said cavities may—in the case of turbine components—adversely affect or even completely impede functionality, such as cooling, in the as-manufactured component.

(18) Although this is not explicitly indicated in the Figures, the presented inventive method may comprise the application and/or adjustment of any expedient or reasonable frequency or frequency range (cf. above). Said frequency may e.g. be known or easy to determine by experimentation of a skilled person.

(19) Particularly, the applied frequencies are advantageously chosen by an operator of the apparatus 100—possibly depending on a particle fraction, the type of base material and the dimensions of the component. The shaking frequency or actuation of the component 10 for powder removal may extend over a large frequency range.

(20) During the actuation, an orientation of the component—as mentioned above—is advantageously varied such that excess material or any base material remaining in the cavity, can efficiently be removed, from convoluted or intricate regions of the cavity (for the sake of simplification, the cavity 3 is only depicted with a simple geometry).

(21) Although this is not explicitly shown in FIG. 1, the cavity 3 expediently comprises an opening (cf. numeral 5 in FIG. 2) which is advantageously necessary for the functionality of the cavity 3 of the component 10 as well as for the described powder removal.

(22) In case that the described opening 5 of the cavity is not already facing upwards such that the base material is trapped inside, the apparatus 100 may need to be readjusted or changed in its orientation (cf. orientation OR′ in FIG. 2) the platform 130 turned or rotated such that the opening 5 is directed downwards, for example.

(23) Further, the apparatus 100 may comprise a blocking mechanism. The blocking mechanism may comprise blocking features as indicated by 136 in FIG. 1. The blocking mechanism is advantageously configured such that, during a variation of the orientation (cf. FIG. 2 below) and/or during actuation, the platform 130 is, e.g. stepwise engageable, e.g. via the blocking features 136. The blocking mechanism 136 is advantageously intended for a reliable blocking of the platform 130 for safety reasons. The blocking mechanism and/of the blocking features may comprise a snap functionality or, e.g. be spring-biased, snap feature, for a releasable blocking of the platform, e.g. with respect to further components of the apparatus 100.

(24) The actuation means 120, as described above advantageously comprises a first vibration generator VG1 being configured for actuating the component 10 and/or the base material 2 at the first frequency F1. The first vibration generator VG1 may allow for an actuation and/or vibration of the component for large amplitudes and/or momentums and advantageously low frequencies, which may particularly be expedient for the removal of powder from heavy parts, e.g. weighing several tens of kilograms.

(25) The actuation means 120 advantageously further comprises a second vibration generator VG2 which is advantageously separate and independently controllable from the first vibration generator. The second vibration generator is further configured for actuating the component 10 at the second frequency F2. The second vibration generator VG2 may particularly allow for a removal of any remaining base material in the cavity 7 and for high frequencies and advantageously smaller amplitudes, momentums or impacts, e.g. possibly necessary for lighter smaller components.

(26) Although this is not explicitly indicated, the apparatus 100 and/or the fixing means 110 may comprise a damping mechanism which is advantageously configured to allow vibration of the component 10, however preventing excessive or adverse transfer of vibrations from the component to the fixing means 110 and/or the actuation means 120.

(27) Further, it is shown in FIG. 1 that the apparatus 100 comprises a rack 132. The rack 132 may comprise a frame, e.g. from steel in order to provide for a stabilizing base e.g. for further components of the apparatus 100. The fixing means 110 are provided in an upper part of the rack 132.

(28) For any turn or changed orientation of the component, mounted to the platform 130, a user of the apparatus 100 and/or an operator may manipulate an adjustment wheel or handle 131.

(29) For any axis of rotation (cf. X and Y), a separate handle may be provisioned (not indicated). Said handle(s) may be connected or coupled to the platform 130 via a worm gear, for example.

(30) The apparatus 100 is advantageously configured movable. Accordingly, the apparatus 100 may comprise rollers 133. The rollers 133 may be mounted to the rack 132, as described above. A number of four rollers 133 may e.g. be provisioned. Said rollers 133 may be provided with brakes 135, e.g. such that each of the rollers 133 may individually be blocked for safety reasons.

(31) The apparatus 100 further comprises a cleaning means 134, such as a cleaning means driven by pressurized air, for example. Said cleaning means may comprise a hose and/or nozzle or any other expedient features for a thorough removal of base material 2 e.g. from the surfaces of the component 10.

(32) FIG. 2 indicates schematically and in form of a partial image of a setup of the platform 130 and the component 10 fixed to it that the component 10 has been turned or rotated (cf. arrow B) by an angle of e.g. 90° in a clockwise sense, i.e. from the orientation OR to the indicated orientation OR′.

(33) The component 10 may comprise a base section 11. Accordingly, the component 10 is advantageously an at least partly hollow component of a gas turbine, such as a turbine airfoil, vane or blade, which is advantageously to be additively manufactured with an internal cavity. Said cavity may serve as a cooling channel for an efficient cooling of the component e.g. during an operation of the turbine. An internal space, or cavity is again denoted by numeral 3 indicating exemplarily e.g. the mentioned cooling channels.

(34) The base section may be a root section of the turbine blade.

(35) The component 10 further comprises an opening 5 by means of which an outside of the component 10 may communicate with the cavity 3. Through the opening 5, the base material 2 may expediently be removed from the cavity 3. To this effect, the orientation OR′ allows the base material 2 to trickle out of the cavity 3 as indicated by arrow C. This is because the cavity is shaped such that—according to the mentioned orientation—the base material 2 may no longer trapped inside the cavity.

(36) For an efficient removal of the base material 2, the present invention may comprise superposing the mentioned first frequency F1 and the mentioned second frequency F2 and/or the respective frequency ranges.

(37) The first frequency or frequency range F1 may comprise frequencies from several mHz to 1 Hz.

(38) Advantageously, the first frequency F1 is lower than the second frequency F2, such that the base material 2 may efficiently be removed from the cavity 3. It may be provisioned, that within the actuation of the component 10, advantageously relative to the base material 2, at the first frequency F1, the whole setup and/or the structure 1 is only actuated very slowly, but advantageously with a fairly large amplitude or momentum from one position to another.

(39) The second frequency F2 or frequency range may span frequencies from 1 Hz to several kHz, for example.

(40) Advantageously, the presented use of the apparatus 100 allows for a complete removal of the base material from the cavity as shown in FIG. 2 such that said cavity is advantageously free of excess powder or base material and the advantages or properties of the respective cavities or internal spaces can be exploited in the readily manufactured component.

(41) The scope of protection of the invention is not limited to the examples given hereinabove. The invention is embodied in each novel characteristic and each combination of characteristics, which particularly includes every combination of any features which are stated in the claims, even if this feature or this combination of features is not explicitly stated in the claims or in the examples.