A heat exchange system for a vehicle includes: a first cooling circuit (L1-1, L1-2) is configured to cool an internal combustion engine; a second cooling circuit (L2-1, L2-2) is configured to cool a driving electric motor outputs a driving force; a first heat exchanger (106) is configured to exchange heat between the first cooling circuit and the second cooling circuit; a first sensor (151) is configured to detect a temperature of the first cooling circuit; a second sensor (152) is configured to detect a temperature of the second cooling circuit; and a controller (155) is configured to execute control of performing heat exchange between a coolant in the first cooling circuit and a coolant in the second cooling circuit using the first heat exchanger when the temperature detected by the first sensor is lower than the temperature detected by the second sensor.

A cooling control device includes a switching valve, an electric motor, and a controller. The switching valve has a coolant outlet. The coolant outlet is configured such that a coolant flows through the coolant outlet. The electric motor is configured to operate the switching valve to switch connecting and shutting off between the coolant outlet and a coolant transporting unit. The controller is configured to determine a duty ratio of a signal for controlling the electric motor on a basis of the temperature of the coolant over a predetermined period of time after the electric motor starts operating the switching valve.

Examples of techniques for controlling a cooling system for an internal combustion engine using feedback linearization are provided. In one example implementation, a computer-implemented method includes receiving, by a processing device, desired temperature targets. The method further includes receiving, by the processing device, temperature feedbacks. The method further includes calculating, by the processing device, a desired temperature derivative for each of the desired temperature targets. The method further includes calculating, by the processing device, desired coolant flows from the desired temperature derivative for each of the desired temperature targets using feedback linearization. The method further includes calculating, by the processing device, actuator commands from the desired coolant flows using an inverted hydraulic model. The method further includes implementing, by the processing device, the actuator commands in actuators in the cooling system.

Examples of techniques for controlling a cooling system for an internal combustion engine using feedback linearization are provided. In one example implementation, a computer-implemented method includes receiving, by a processing device, desired temperature targets. The method further includes receiving, by the processing device, temperature feedbacks. The method further includes calculating, by the processing device, a desired temperature derivative for each of the desired temperature targets. The method further includes calculating, by the processing device, desired coolant flows from the desired temperature derivative for each of the desired temperature targets using feedback linearization. The method further includes calculating, by the processing device, actuator commands from the desired coolant flows using an inverted hydraulic model. The method further includes implementing, by the processing device, the actuator commands in actuators in the cooling system.

A bleed air cooling system for a gas turbine engine includes a bleed port located at an axial location of the gas turbine engine to divert a bleed airflow from a gas turbine engine flowpath, a bleed outlet located at a cooling location of the gas turbine engine and a bleed duct in fluid communication with the bleed port and the configured to convey the bleed airflow from the bleed port to the bleed outlet. A modulating valve is located at the bleed duct and is movable between a fully open position and a fully closed position to regulate the bleed airflow through the bleed duct based on one or more operating conditions of the gas turbine engine.

A cooling system for an internal combustion engine of a motor-vehicle presenting a circuit for a coolant of the engine. The circuit includes a thermally insulated tank for the coolant of the engine, connected to an outer portion of the cooling circuit. The tank is arranged in the circuit to retain a defined quantity of coolant at a temperature above the ambient temperature when the engine is inactive, and for causing this quantity of coolant to flow, at a temperature above the ambient temperature, into the cooling circuit of the engine, after a subsequent start of the engine, during an engine warm up stage. The circuit also includes an expansion vessel connected to the outer circuit portion of the coolant of the engine. The expansion vessel has a thermally insulated body and constitutes the thermally insulated tank for the engine coolant.

Methods are provided for engine coolant system diagnostics. In one example, engine coolant system malfunction is indicated based on an engine coolant temperature inference model, whereas in another example engine coolant system malfunction is indicated based on a time-based monitor, where the inference model is enabled at ambient temperatures above a predetermined threshold, and where the time-based monitor is enabled at ambient temperatures below the predetermined threshold. In this way, accurate engine coolant system diagnosis may be accomplished under ambient temperature conditions wherein the engine coolant temperature inference model may be compromised.

A method for improving the performance of a motor vehicle which has a cooler and a fan for cooling the vehicle's engine, the method includes detecting (s410) a temperature-related parameter which affects the engine's temperature during specific cooling conditions; and activating operation of the fan when the engine's temperature fulfils a predetermined condition; determining the (s440) predetermined condition on the basis of outcome as regards engine temperature over a predetermined period of time, and/or outcome as regards the detected parameter over a predetermined period of time. A computer program product includes program code (P) for a computer (200; 210) for implementing a method according to the invention. Also the device that performs the method and a motor vehicle equipped with the device are disclosed.

A bleed air cooling system for a gas turbine engine includes a bleed port located at an axial location of the gas turbine engine to divert a bleed airflow from a gas turbine engine flowpath, a bleed outlet located at a cooling location of the gas turbine engine and a bleed duct in fluid communication with the bleed port and the configured to convey the bleed airflow from the bleed port to the bleed outlet. A modulating valve is located at the bleed duct and is movable between a fully open position and a fully closed position to regulate the bleed airflow through the bleed duct based on one or more operating conditions of the gas turbine engine.