Impingement cooling of gas turbine blades or vanes

The invention claimed is: 1. A turbine component, comprising: a hollow aerofoil and an impingement tube located within the hollow aerofoil, wherein the hollow aerofoil includes a cavity including opposed rear and fore portions defined by interior surfaces of respective trailing edge and leading edge regions of the hollow aerofoil, wherein the rear portion includes a sharp edge portion and the fore portion includes a substantially cylindrical portion, wherein the sharp edge portion of the rear portion of the cavity in the trailing edge region has a curved and/or twist shape with a sharp edge at an end, said impingement tube being formed from at least two separate sections corresponding to a rear section and a fore section that are configured to extend span wise through the hollow aerofoil, wherein the rear and fore sections respectively have substantially a same contour as the respective rear and fore portions of the cavity, wherein the rear and fore sections of the impingement tube are connected together by a locking device, said locking device being insertable into the hollow aerofoil so as to urge the rear and fore sections of the impingement tube into locking engagement with portions of the interior surfaces that define the opposed rear and fore portions of the cavity of the hollow aerofoil, wherein said locking device is a roll pin being located in an axially direction between the rear and fore sections of the impingement tube and has a main extension which extends in a radial direction of the hollow aerofoil. 2. The turbine component according to claim 1 , wherein said hollow aerofoil comprises a single cavity. 3. The turbine component according to claim 1 , wherein at least one of said at least two separate sections extends substantially completely through a span of the hollow aerofoil. 4. The turbine component according to claim 1 , wherein the turbine component is a turbine blade or vane. 5. The turbine component according to claim 1 , wherein said hollow aerofoil comprises protrusions or locking pins or ribs at an interior surface of said hollow aerofoil. 6. An impingement tube configured to mount within a hollow aerofoil of a turbine component, which hollow aerofoil includes a cavity including opposed rear and fore portions defined by interior surfaces of respective trailing edge and leading edge regions of the hollow aerofoil, wherein the rear portion includes a sharp edge portion and the fore portion includes a substantially cylindrical portion, wherein the sharp edge portion of the rear portion of the cavity in the trailing edge region has a curved and/or twist shape, said impingement tube comprising: at least two separate sections corresponding to a rear section and a fore section that are configured to extend span wise through the hollow aerofoil, wherein the rear and fore sections respectively have substantially a same contour as the respective rear and fore portions of the cavity, wherein the rear and fore sections of the impingement tube are connected together by a locking device, said locking device being insertable into the hollow aerofoil so as to urge the rear and fore sections of the impingement tube into locking engagement with portions of the interior surfaces that define the opposed rear and fore portions of the cavity of the hollow aerofoil, wherein said locking device is a roll pin being located in an axially direction between the rear and fore sections and has a main extension which extends in a radial direction of the hollow aerofoil when the impingement tube is mounted within the hollow aerofoil. 7. A method for assembling an impingement tube in a hollow aerofoil of a turbine component, which hollow aerofoil includes a cavity including opposed rear and fore portions defined by interior surfaces of respective trailing edge and leading edge regions of the hollow aerofoil, wherein the rear portion includes a sharp edge portion and the fore portion includes a substantially cylindrical portion, wherein the sharp edge portion of the rear portion of the cavity in the trailing edge region has a curved and/or twist shape, wherein the impingement tube is formed from at least two separate sections corresponding to a rear section and a fore section that are configured to extend span wise through the hollow aerofoil, wherein the rear and fore sections respectively have substantially a same contour as the respective rear and fore portions of the cavity, said method comprising: inserting the rear section of the impingement tube into the hollow aerofoil and maneuvering the rear section in a direction of the trailing edge region of the hollow aerofoil into a position in the rear portion of the cavity of the hollow aerofoil, inserting the fore section of the impingement tube into the hollow aerofoil adjacent to the rear section, connecting the rear and fore sections of the impingement tube together by inserting into the hollow aerofoil a locking device which is a roll pin in an axial direction between the rear and fore sections and which has a main extension which extends in a radial direction of the hollow aerofoil, so as to urge the rear and fore sections of the impingement tube into locking engagement with portions of the interior surfaces that define the opposed rear and fore portions of the cavity of the hollow aerofoil. 8. The method according to claim 7 , wherein the fore section of the impingement tube is maneuvered into position in the fore portion of the cavity of the hollow aerofoil.