Blade root receptacle for receiving a blade root of a rotor blade of a turbomachine. The blade root receptacle, for radially bearing in a form-fitting manner on the blade root, has a supporting flank which, in terms of a rotation axis, at least in proportions faces radially inward, wherein the supporting flank is provided with a convexity which, when viewed in an axially perpendicular section, at least in portions has a convex shape and, also when viewed in an axially parallel section, at least in portions has a convex shape.

Disclosed is an aircraft turbine engine (10), comprising a gas generator (12) and a fan (14) arranged upstream from the gas generator (12) and configured to generate a gas inlet stream (F), part of which flows into a duct of the gas generator to form a primary stream (36), the turbine engine (10) comprising an electrical machine that is mounted coaxially downstream from the fan (14) and that comprises a rotor (62a) surrounded by a stator (62b) carried by an annular shroud (64), this shroud (64) being surrounded by a casing (40) of the gas generator that defines, with this shroud (64), a section of the flow duct for the primary stream (36), stationary vanes (42, 68) for straightening this primary stream (36) extending into this path.

A combustion engine component is disclosed. The combustion engine component comprises a body that includes a first surface in operative thermal communication with a hot combustion gas, and a second surface in operative fluid communication with a cooling fluid. Also, as disclosed in greater detail below, the second surface includes a first surface contour feature configured to increase a contact angle of a liquid on the second surface.

A rotor blade attached to a rotor shaft rotatable around an axis includes: a blade body extending in a radial direction with respect to the axis and having a blade-shaped cross section orthogonal to the radial direction; a shroud provided at an end of the blade body on a radial outer side, and a seal fin protruding from the shroud toward an outer circumferential side, and the seal fin includes: a seal fin body extending in a plate shape in a circumferential direction; and a reinforcing portion provided on at least one plate surface of the seal fin body to increase a thickness of the seal fin, the reinforcing portion gradually increasing in dimension in the radial direction toward the center in the circumferential direction.

An assembly for a turbine engine is provided. This turbine engine assembly includes a shell and a heat shield with a cooling cavity between the shell and the heat shield. The heat shield defines a plurality of cooling apertures and an indentation in a side of the heat shield opposite the cooling cavity. The cooling apertures are fluidly coupled with the cooling cavity. The indentation is configured such that cooling air, directed from a first of the cooling apertures, at least partially circulates against the side of the heat shield.

A seal assembly includes a rotating seal runner having an outer radial surface, and one or more rotationally stationary seal rings located radially outboard of the seal runner. Each seal ring has an inner radial surface, with the inner radial surface and the outer radial surface defining a sealing interface therebetween. An axially extending shape of the inner radial surface is selected utilizing a predicted shape of the outer radial surface at a selected operating condition of the seal assembly.

A cooling structure on a trailing-edge cutback of a turbine blade, including a plurality of lands, a trailing edge cutback and a dimple group. Adjacent lands are arranged on wall surfaces at two sides of the trailing edge cutback. The wall surfaces are each provided with the dimple group including multiple dimples. An extension direction of at least one dimple forms an inclined angle with the land on one side, and/or an extension direction of at least one dimple forms an inclined angle with the land on the opposite side. The cooling air enters the trailing edge, and after passing through pin fins, then flows over the dimples along the cutback surface to generate a spiral vortex which is guided to the lands on both sides thereof.

A cooling structure on a trailing-edge cutback of a turbine blade, including a plurality of lands, a trailing edge cutback and a dimple group. Adjacent lands are arranged on wall surfaces at two sides of the trailing edge cutback. The wall surfaces are each provided with the dimple group including multiple dimples. An extension direction of at least one dimple forms an inclined angle with the land on one side, and/or an extension direction of at least one dimple forms an inclined angle with the land on the opposite side. The cooling air enters the trailing edge, and after passing through pin fins, then flows over the dimples along the cutback surface to generate a spiral vortex which is guided to the lands on both sides thereof.

A flow path component assembly includes a carrier that has at least one radially extending tab. A flow path component has a base portion and a first wall that extends radially from the base portion. The first wall has an aperture. A pin extends through a hole in the radially extending tab and the aperture. The pin has an ellipsoid portion between a first end and a second end.

A flow path component assembly includes a carrier that has at least one radially extending tab. A flow path component has a base portion and a first wall that extends radially from the base portion. The first wall has an aperture. A pin extends through a hole in the radially extending tab and the aperture. The pin has an ellipsoid portion between a first end and a second end.