Abstract: There is disclosed a method for the production of a three-dimensional product (2) via an additive layer manufacturing process such as an electron beam manufacturing process to selectively fuse parts (17) of a powder bed (16), said parts (17) corresponding to successive cross-sections of the product (2). The method involves the use of said additive layer manufacturing process to form a tool (12) by selectively fusing additional parts (18) of the powder bed (16), said additional parts (18) corresponding to successive cross-sections of the tool (12). The method also comprises a subsequent step of manipulating the tool (12) perform a processing function on the product (2).

Abstract: A method of manufacturing a component using electron beam melting includes providing a powder layer; selectively melting at least a part of the powder layer so as to generate a solid layer of the component using a first electron beam; identifying any defects in the solid layer by scanning the solid layer using a second electron beam; and then repeating these steps at least once so as to build up a shape corresponding to the component. The second electron beam has a lower power than the first electron beam. The method may also include steps of removing any identified defects in the solid layer by using the first electron beam to re-melt at least a part of the solid layer, and adjusting one or more parameters of the selective melting step so as to avoid future recurring defects based on stored data relating to the scanned solid layer.

Abstract: A method of manufacturing and measuring the geometry of at least a part of a component, and a method of manufacturing a component, both include providing a powder layer to a melt region; selectively melting the powder layer using an energy source, the melted powder subsequently solidifying to form a solid layer; scanning the melt region, including the solid layer, using a scanning electron beam; detecting backscattered electrons resulting from the interaction of the scanning electron beam with the melt region; determining the geometry of the solid layer from the detected backscattered electrons; and storing data relating to the determined geometry of the solid layer. The methods may also include adjusting parameters of the steps of providing a powder layer and/or selectively melting the powder layer to avoid future recurring errors, or generating a virtual 3-D model of the manufactured component, using the stored data.

Abstract: A method of manufacturing a component includes providing a powder layer; scanning the powder layer using an electron beam; detecting back scattered electrons produced by the interaction of the electron beam with the powder layer; identifying, from the detected back scattered electrons, any defects in the powder layer; selectively melting at least a part of the powder layer so as to generate a solid layer; and repeating these steps at least once so as to build up a shape corresponding to the component. The method may also includes steps of making a decision about whether to remove any identified defects in the powder layer, and adjusting one or more parameters of the step of providing a powder and/or adjusting one or more parameters of the selective melting step so as to avoid future recurring defects at that position based on stored data relating to the scanned powder layer.

Abstract: There is disclosed a method for the production of a three-dimensional product (2) via an additive layer manufacturing process such as an electron beam manufacturing process to selectively fuse parts (17) of a powder bed (16), said parts (17) corresponding to successive cross-sections of the product (2). The method involves the use of said additive layer manufacturing process to form a tool (12) by selectively fusing additional parts (18) of the powder bed (16), said additional parts (18) corresponding to successive cross-sections of the tool (12). The method also comprises a subsequent step of manipulating the tool (12) perform a processing function on the product (2).

Abstract: An additive layer manufacture machine generates a first electron beam for scanning a powder layer to be melted in a selective melting process. Backscatter electrons from the interaction between the first electron beam and the powder layer is detected by a backscatter detector. Any defects in the powder layer can then be identified, or inferred, from the detected backscatter electrons. If necessary, any defects can be removed from the powder layer before selective melting. Once the powder layer has been inspected and if necessary improved, selective melting of the layer is performed in order to produce a layer of the component. The process may be repeated to generate a finished component with good mechanical properties.

Abstract: An additive layer manufacture (ALM) machine generates a first electron beam for selectively melting a layer of metal powder, and a second electron beam for detecting defects in the selectively melted layer once it has solidified. The second electron beam has a lower power than the first electron beam so as to be used to identify any defects without performing further melting. If any defects are detected, they can be removed, for example by re-melting, before the next layer of powder is supplied. The process may be repeated to generate a finished component with good mechanical properties.

Abstract: An additive layer manufacture (ALM) machine comprises an energy source (180) for selectively melting a layer of metal powder (500), and an electron beam (110) for determining the shape of the selectively melted solid layer (320) once it has solidified. The shape is determined by detecting backscattered electrons (130) from the interaction between the electron beam (110) and the solid layer (320). If the shape of the solid layer (320) is outside a determined tolerance, it may be corrected before proceeding. The process may be repeated to generate a finished component (300) with good mechanical properties and accurate geometry.

Abstract: An additive layer manufacturing method includes the steps of: a) laying down powder layer on powder bed, and b) focussing energy on an area of powder layer to fuse area of powder layer and thereby form a cross-section of the product; wherein steps a) and b) are repeated to form successive cross-sections of product, and wherein at least one of said steps b) involves focussing energy on an area of respective powder layer which is unsupported by a previously formed cross-section of product to thereby form a downwardly facing surface of product. Method is at least some of said successive steps b) involve focussing energy on a support area of respective powder layer, to fuse support area and thereby form successive cross-sections of a support pin within powder bed, support pin extending outwardly from downwardly facing surface of product when it is formed, so as to support downwardly facing surface.