A turbomachine equipped with an embedded electric machine having a segmented and movable stator is provided. In one aspect, a turbomachine defines a radial direction and includes a rotating component, actuators, and an electric machine. The electric machine includes a rotor assembly rotatable with and operatively coupled with the rotating component. The electric machine also includes a stator assembly having a stator split into stator segments. Each one of the stator segments is movable by one of the actuators between a first position and a second position along the radial direction, the stator segments each being closer to the rotor assembly along the radial direction when in the first position than when in the second position.

A propulsion system coupled to a vehicle. The system includes a diffusing structure and a conduit portion configured to introduce to the diffusing structure through a passage a primary fluid produced by the vehicle. The passage is defined by a wall, and the diffusing structure comprises a terminal end configured to provide egress from the system for the introduced primary fluid. A constricting element is disposed adjacent the wall. An actuating apparatus is coupled to the constricting element and is configured to urge the constricting element toward the wall, thereby reducing the cross-sectional area of the passage.

In accordance with at least one aspect of this disclosure, embodiments of fluid pumps, pump cases, valve bodies, and volutes are disclosed herein. Embodiments of methods for manufacturing fluid pumps, pump cases, valve bodies, and volutes are also disclosed herein. Embodiments can include additive manufacturing, for example. Certain embodiments can include additively manufacturing a pump case in a tilted orientation, utilizing only coincidental support structure having a unique shape, and with teardrop shaped volute and/or valve body.

A gas turbine engine component includes a structural component having a surface, the structural component having an organic matrix composite material; and a cured thermal barrier layer on the surface, wherein the cured thermal barrier layer is a pre-ceramic layer including inorganic matrix containing silicon oxides reinforced with glass or quartz fibers.

A method is provided for manufacturing a composite body. A first longitudinal portion of a continuous length of prepreg material is shaped using a first die of a compression molding tool to provide a shaped first longitudinal portion of the continuous length of prepreg material. The shaped first longitudinal portion is consolidated using the compression molding tool to provide a first portion of the composite body. The first portion of the composite body is moved out of the compression molding tool. The first die is swapped for a replacement first die. A second longitudinal portion of the continuous length of prepreg material is shaped using the replacement first die of the compression molding tool to provide a shaped second longitudinal portion of the continuous length of prepreg material. The shaped second longitudinal portion is consolidated using the compression molding tool to provide a second portion of the composite body.

An airfoil includes an airfoil section that has an internal cavity and first and second endwall sections between which the airfoil section is disposed. The first endwall section includes a guide portion that has a guide opening flanked by first and second bearing lands. The first bearing land is between the guide opening and a first port in the first endwall section that opens to the internal cavity of the airfoil section. The second bearing land is between the guide opening and a second port in the first endwall section that also opens to the internal cavity. A tie member extends through the internal cavity and secures the first and second endwall sections together to trap the airfoil section. The tie member extends through the guide opening in the first endwall section. A spring member on the first and second bearing lands tensions the tie member.

A splitter between a primary flow and a secondary flow of a dual flow turbomachine includes a single-piece structure including an outer annular wall, an inner annular wall, a radial annular wall and an inner annular baffle, defining a first cavity between the outer annular wall and the inner annular baffle, and a second cavity between the inner annular wall, the radial annular wall and the inner annular baffle.

A section of a gas turbine engine includes a ceramic component and a metallic component situated adjacent the ceramic component. The ceramic component and the metallic component are situated outside of a core flow path of the gas turbine engine. The section of a gas turbine engine also includes an interface between the ceramic component and a metallic component and a mullite-based coating disposed at the interface. The coating provides thermal protection to the ceramic component and the metallic component, and provides thermochemical protection against interaction between the ceramic component and the metallic component. A gas turbine engine and a method of protecting components in a gas turbine engine are also disclosed.

A turbine exhaust structure for an intermediate-pressure exhaust end of a high-and-intermediate-pressure (HIP) module.

A shroud for a turbine engine includes a body having a first surface with an inlet fluidly coupled to a cooling fluid flow, and a second surface facing a heated fluid flow. A cavity within the body can be fluidly coupled to the inlet and include an impingement zone thermally coupled to the second surface.