A coolant system of a generator arranged to be driven by an aircraft engine. The coolant system includes a fluid circuit with a fluid therein, the fluid for cooling an electricity generator, and a pump, arranged to provide a flow of fluid around the fluid circuit to deliver coolant to at least one cooled component of the generator, via a cooler. The system also includes a fluid control device located between the pump and the cooler in the fluid circuit. The fluid control device is configured to selectively direct the fluid provided by the pump away from the cooler in dependence on a measured pressure in the fluid circuit. The measured pressure is derived from a measured point in the fluid circuit, the measured point being remote from the fluid control device.

A coolant system of a generator arranged to be driven by an aircraft engine. The coolant system includes a fluid circuit with a fluid therein, the fluid for cooling an electricity generator, and a pump, arranged to provide a flow of fluid around the fluid circuit to deliver coolant to at least one cooled component of the generator, via a cooler. The system also includes a fluid control device located between the pump and the cooler in the fluid circuit. The fluid control device is configured to selectively direct the fluid provided by the pump away from the cooler in dependence on a measured pressure in the fluid circuit. The measured pressure is derived from a measured point in the fluid circuit, the measured point being remote from the fluid control device.

A rotary electric machine includes a stator, a rotor, a housing, a cooling liquid introduction room, and a lubricating liquid introduction room. The rotary electric machine further includes a first seal member, a second seal member, and a leakage liquid discharge hole. The first seal member regulates a leakage of the cooling liquid to a lubricating liquid introduction room direction from the cooling liquid introduction room. The second seal member regulates a leakage of the lubricating liquid to a cooling liquid introduction room direction from the lubricating liquid introduction room. The leakage liquid discharge hole is arranged between the first seal member and the second seal member. The leakage liquid discharge hole discharges the cooling liquid that is leaked through the first seal member and the lubricating liquid that is leaked through the second seal member to an outside of the housing.

An electric machine with a rotor (4) rotatably disposed within a stator (1) with a stator winding (3) has a plurality of permanent magnets (8) received therein. A casing (17) encloses the stator and the rotor, and an impeller (13) with blades is fixed to an axle (7) of the rotor so as to generate a flow of air through the casing for cooling end-turns (25) of the stator winding by drawing air through an inlet opening (18) at one end of the casing and blowing it out of the casing through an outlet opening (19) at the other end of the casing. At least one shutter is arranged to close the outlet opening (19) when the temperature of the cooling air through the outlet opening reaches a predetermined level well above a maximum level of the temperature possible to be reached under normal operation of the electric machine so as to close the outlet opening upon occurrence of arcing in the end-turns. A temperature dependent member is arranged in the air flow through the outlet opening to obtain such closing.

An electric machine with a rotor (4) rotatably disposed within a stator (1) with a stator winding (3) has a plurality of permanent magnets (8) received therein. A casing (17) encloses the stator and the rotor, and an impeller (13) with blades is fixed to an axle (7) of the rotor so as to generate a flow of air through the casing for cooling end-turns (25) of the stator winding by drawing air through an inlet opening (18) at one end of the casing and blowing it out of the casing through an outlet opening (19) at the other end of the casing. At least one shutter is arranged to close the outlet opening (19) when the temperature of the cooling air through the outlet opening reaches a predetermined level well above a maximum level of the temperature possible to be reached under normal operation of the electric machine so as to close the outlet opening upon occurrence of arcing in the end-turns. A temperature dependent member is arranged in the air flow through the outlet opening to obtain such closing.

A fluid apparatus includes a hydraulic machine, a rotary electric machine connected to the hydraulic machine, and a power conversion controller that converts power from the rotary electric machine. A non-normal operation is performed in a warning state that differs from a normal state in which a normal operation is continued and an anomalous state in which operation is stopped to continue a stopped condition.

A cooling apparatus includes: an intra-axle coolant supply unit supplying coolant into a rotation shaft of a rotating electrical machine; a coolant discharge unit pouring coolant onto the rotating electrical machine, wherein the coolant is conducted in a predetermined distribution ratio to the intra-axle coolant supply unit and the coolant discharge unit; a flow rate adjustment device capable of adjusting a supply flow rate of the coolant; and a control device functioning as: a determination device determining overheating of the rotating electrical machine caused by deviating allocation of the coolant to the intra-axle coolant supply unit in an increase direction as compared to the predetermined distribution ratio; and a recovery device controlling the flow rate adjustment device to implement a recovery operation in which the supply flow rate is decreased and then elevated, when the determination device has determined that the overheating of the rotating electrical machine is occurring.

A cooling apparatus includes: an intra-axle coolant supply unit supplying coolant into a rotation shaft of a rotating electrical machine; a coolant discharge unit pouring coolant onto the rotating electrical machine, wherein the coolant is conducted in a predetermined distribution ratio to the intra-axle coolant supply unit and the coolant discharge unit; a flow rate adjustment device capable of adjusting a supply flow rate of the coolant; and a control device functioning as: a determination device determining overheating of the rotating electrical machine caused by deviating allocation of the coolant to the intra-axle coolant supply unit in an increase direction as compared to the predetermined distribution ratio; and a recovery device controlling the flow rate adjustment device to implement a recovery operation in which the supply flow rate is decreased and then elevated, when the determination device has determined that the overheating of the rotating electrical machine is occurring.

An assembly and a method for preventing an axial migration of a spring in a generator rotor are presented. The assembly includes a step pin radially disposed through an amortisseur and inserted into a spring of the generator rotor. The step pin is arranged axially apart from an adjacent radial vent passage and radially extends through the spring into a slot clearance between the spring and a creepage. The amortisseur includes a counter bore to retain a pin head and a pin shoulder. The spring includes a pin hole for a pin body extending therethrough. Diameters of the counter bore and the pin hole are smaller than diameters of amortisseur radial vent aperture and spring radial vent aperture. The step pin prevents an axial migration of the spring in rotor slots.

A generator includes a stator core having a set of stator poles formed by a post and a wire wound about the post to form a stator winding, with the stator winding having end turns, a rotor having a set of rotor poles and configured to rotate relative to the stator and a rotor channel for liquid coolant to flow through the rotor to a set of coolant apertures, and a set of rotor pole coolant channels aligned with and proximate to the set of rotor poles. The liquid coolant flow extracts heat from the generator.