A thermal energy management system for an internal combustion engine of a motor vehicle includes a coolant circuit including the internal combustion engine and a first heat exchanger. The coolant circuit is configured to convey a coolant therethrough. The thermal energy management system includes a gas circuit including the internal combustion engine, the first heat exchanger, and an exhaust line configured to convey an exhaust gas produced by the engine from the gas circuit. The first heat exchanger exchanging heat energy between the coolant flowing through the coolant circuit and the exhaust gas flowing through the gas circuit.

A system for cooling an engine of a mild hybrid vehicle includes an engine that includes a plurality of combustion chambers generating driving torque by combustion of a fuel, an integrated starter-generator, a clutch that selectively transmits the driving torque to a transmission, a driving information detector that detects driving information of the vehicle, a cooling line through which a coolant for cooling the combustion chamber flows, a heat storage tank disposed at the cooling line, and that temporarily stores the coolant, and a controller that controls an inflow coolant amount flowing in the heat storage tank and an exhaust coolant amount exhausting from the heat storage tank depending on the driving information of the vehicle detected by the driving information detector.

A heating and cooling system for an internal combustion engine comprising a heat storage circuit and a radiator circuit, and a method of controlling such a system are disclosed. The heat storage circuit comprises a heat storage container in which engine coolant is stored and allowed to flow into and out of. The radiator circuit comprises a radiator for flow of the engine coolant, and the radiator has a radiator inlet connected via an upstream radiator conduit to a coolant outlet of the engine, and a radiator outlet connected via a downstream radiator conduit to a coolant inlet of the engine. A bypass conduit is connected between the upstream radiator conduit and the downstream radiator conduit to allow coolant to bypass the radiator. A thermostat controlled valve is arranged in the upstream radiator conduit at a coolant outlet of the engine and connected to the bypass conduit.

A warm-up device is provided in a cooling-water circuit, through which cooling water is circulated so as to pass through an engine. The warm-up device has a heat accumulating passage, in which a heat accumulating device is provided, and an accumulating-device bypassing passage bypassing the heat accumulating device. A waste-heat collecting device is provided in the cooling-water circuit so that heat is collected from exhaust gas from the engine and such collected heat is accumulated in the heat accumulating device. The cooling water is circulated through the heat accumulating device during a start-up operation of the engine in order to heat the cooling water flowing into the engine so as to quickly warm up the engine.

A tank stores a coolant liquid and an engine and/or transmission lubricant for a motor vehicle heat engine, as well as a circuit for the cooling and heat regulation of that engine.

The tank has a thermally insulating outer wall including an inlet and an outlet for this liquid, and inside the wall, it comprises heating means that are able to preheat this liquid for the cold engine start of the vehicle.

The tank further includes a first compartment for this liquid that is provided with said inlet and said outlet, and at least one other compartment that is appropriate for storing an engine or transmission lubricant and that is separated from the first compartment by a tight partition in a lower zone of the first compartment, these compartments each containing at least one local heating means as heating means.

An exhaust device of an engine, with an exhaust path to lead exhaust gas discharged from the engine to outside, the exhaust device comprising: an exhaust heat collector being configured to collect heat from the exhaust gas, and a cooling part being configured to cool down the exhaust heat collecting part from an outer peripheral side via a cooling fluid; and an exhaust gas flow controlling member in a cylindrical shape, comprising an inlet part and an outlet part where the inflow of the exhaust gas is discharged to an upstream side of the exhaust heat collecting part. An opening diameter of the outlet part is arranged to be smaller than an outer diameter of the exhaust heat collecting part. The exhaust gas flow controlling member is placed so that an open end of the outlet part opposes a central portion of an upstream end plane of the exhaust heat collecting part. The open end of the outlet part and the upstream end plane of the exhaust heat collecting part are a predetermined distance apart.

A system for controlling a flow rate of air into a vehicle engine compartment, may include a radiator cooling a coolant; a coolant inflow tank provided to one side of the radiator and temporarily storing the coolant that cools an engine; and a coolant exhaust tank provided to another side of the radiator and temporarily storing the coolant circulating past a cooling fin of the radiator from the coolant inflow tank.

A system for cooling an engine of a mild hybrid vehicle includes an engine that includes a plurality of combustion chambers generating driving torque by combustion of a fuel, an integrated starter-generator, a clutch that selectively transmits the driving torque to a transmission, a driving information detector that detects driving information of the vehicle, a cooling line through which a coolant for cooling the combustion chamber flows, a heat storage tank disposed at the cooling line, and that temporarily stores the coolant, and a controller that controls an inflow coolant amount flowing in the heat storage tank and an exhaust coolant amount exhausting from the heat storage tank depending on the driving information of the vehicle detected by the driving information detector.

A thermoregulation system, especially for automobiles, the thermoregulation system including an exhaust-gas outlet for discharging exhaust gas from the engine, an engine gas inlet, an exhaust-gas recirculation circuit between the exhaust-gas outlet and the gas inlet for recirculating at least part of the exhaust gases, a circuit for conducting and/or circulating the coolant in order to cool the engine, whereby the coolant-conducting circuit includes a latent-heat storage unit which receives heat from or transfers heat to the coolant. A first heat exchanger is arranged in the exhaust-gas recycling circuit to exchange heat between the exhaust gas and the coolant. A means for controlling the flow includes at least one valve and at least one branch for controlling the heat exchange in the first heat exchanger. An oil-feed circuit is provided for heating or cooling the oil and includes a second heat exchanger exchanging heat between the oil and the coolant flowing from the first heat exchanger.

A thermal energy storage system has an insulated housing defining an internal volume; a heat storing material contained in said internal volume; a first conduit arrangement configured to carry a first working fluid. The first conduit arrangement extending across said internal volume such that thermal energy is transferrable between the first working fluid and the heat storing material. A second conduit arrangement carries a second working fluid. The second conduit arrangement extends across the internal volume such that thermal energy is transferrable between the heat storing material and the second working fluid. The first working fluid and the second working fluid are fluidly separated from each other inside the housing. The first conduit arrangement and the second conduit arrangement are in contact with each other so that thermal energy is transferrable between the first working fluid and the second working fluid.