Engine thermal management system and method for split cooling and integrated exhaust manifold applications
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02B-029/04
F01P-003/20
F02F-001/36
F02F-001/26
출원번호
US-0589218
(2012-08-20)
등록번호
US-8997483
(2015-04-07)
발명자
/ 주소
Zahdeh, Akram R.
Bosman, Colin Blacklock
출원인 / 주소
GM Global Technology Operations LLC
대리인 / 주소
Quinn Law Group, PLLC
인용정보
피인용 횟수 :
1인용 특허 :
9
초록▼
A thermal management system and method for split cooling and integrated exhaust manifold applications in an automotive engine is provided. The thermal management system includes a cooling circuit that directs coolant through a plurality of components to warm the engine and passenger compartment effi
A thermal management system and method for split cooling and integrated exhaust manifold applications in an automotive engine is provided. The thermal management system includes a cooling circuit that directs coolant through a plurality of components to warm the engine and passenger compartment efficiently, as well as remove excess heat from the engine and promote a constant operating temperature during vehicle operation. The cooling circuit directs liquid coolant, propelled by a coolant pump, through at least one of an engine block cooling jacket, an engine head cooling jacket, and an integrated exhaust manifold (IEM) cooling jacket, along a variety of cooling paths. The cooling circuit also incorporates a plurality of flow control valves to selectively distribute flow of the liquid coolant between a radiator, an engine heater core, and a return path to the coolant pump.
대표청구항▼
1. An engine thermal management system for split cooling and integrated exhaust manifold applications, the system comprising: a coolant pump;an engine block cooling jacket and an engine head cooling jacket, each configured to receive coolant directly from the coolant pump;an IEM cooling jacket confi
1. An engine thermal management system for split cooling and integrated exhaust manifold applications, the system comprising: a coolant pump;an engine block cooling jacket and an engine head cooling jacket, each configured to receive coolant directly from the coolant pump;an IEM cooling jacket configured to receive coolant directly from at least one of the coolant pump and the engine head cooling jacket;a first plurality of multi-port flow control valves configured to receive coolant from each of the engine block cooling jacket, the engine head cooling jacket, and the IEM cooling jacket, the first plurality of multi-port flow control valves including a first flow control valve and a second flow control valve, such that the first flow control valve receives coolant from the engine block cooling jacket and the second flow control valve receives coolant from each of the engine block cooling jacket, the engine head cooling jacket, and the IEM cooling jacket, wherein coolant flows through each one of the first plurality of multi-port flow control valves independently of each of the other ones of the first plurality of multi-port flow control valves;a heater core configured to receive coolant from at least one of the first plurality of multi-port flow control valves;a radiator configured to receive coolant from at least one of the first plurality of multi-port flow control valves;at least one control module configured to regulate the coolant pump and actuate the first plurality of multi-port flow control valves; andwherein the coolant pump is configured to receive coolant from each of the radiator, the heater core, and at least one of the first plurality of multi-port flow control valves. 2. The engine thermal management system of claim 1 wherein the engine head cooling jacket and the engine block cooling jacket receive coolant directly from the coolant pump and the IEM cooling jacket receives coolant directly from the engine head cooling jacket. 3. The engine thermal management system of claim 2 wherein the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket, the second flow control valve further configured to transmit coolant to at least one of the radiator, the heater core, and the coolant pump. 4. The engine thermal management system of claim 2 wherein the first plurality of multi-port flow control valves further includes a third flow control valve, such that: the first flow control valve is configured to receive coolant from the engine block cooling jacket and further configured to occupy a closed position and a first open position, such that the first flow control valve expels coolant to the second flow control valve when occupying the first open position;the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket via the third flow control valve, the second flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the second flow control valve expels coolant to the coolant pump when occupying the first open position and expels coolant to the radiator when occupying the second open position; andthe third flow control valve is configured to receive coolant from the IEM cooling jacket the third flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the third flow control valve expels coolant to the heater core when occupying the first open position and expels coolant to the second flow control valve when occupying the second open position. 5. The engine thermal management system of claim 4 wherein the system further comprises: a second plurality of flow control valves, including at least one on/off valve and a fourth multiport flow control valve, the on/off valve configured to receive coolant from the coolant pump, the fourth multi-port flow control valve configured to receive coolant from at least one of the IEM cooling jacket outlet and the on/off valve;a transmission heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an engine oil heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an exhaust gas recirculation cooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator;an intercooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator;a turbocharger cooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator; andwherein the on/off valve is configured to expel coolant to one of the fourth multi-port flow control valve, the exhaust gas recirculation cooler, the intercooler, and the turbo charger cooler. 6. The engine thermal management system of claim 1 wherein the engine head cooling jacket, the engine block cooling jacket, and the IEM cooling jacket receive coolant directly from the coolant pump as independent circuits. 7. The engine thermal management system of claim 6 wherein the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket, the second flow control valve further configured to transmit coolant to at least one of the radiator, the heater core, and the coolant pump. 8. The engine thermal management system of claim 6 wherein the first plurality of multi-port flow control valves further includes a third flow control valve, such that: the first flow control valve is configured to receive coolant from the engine block cooling jacket and further configured to occupy a closed position and a first open position, such that the first flow control valve expels coolant to the second control valve when occupying the first open position;the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket via the third flow control valve, the second flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the second flow control valve expels coolant to the coolant pump when occupying the first open position and expels coolant to the radiator when occupying the second open position; andthe third flow control valve is configured to receive coolant from the IEM cooling jacket the third flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the third flow control valve expels coolant to the heater core when occupying the first open position and expels coolant to the second flow control valve when occupying the second open position. 9. The engine thermal management system of claim 8 wherein the system further comprises: a second plurality of flow control valves, including at least one on/off valve and a fourth multi-port flow control valve, the on/off valve configured to receive coolant from the coolant pump, the fourth multi-port flow control valve configured to receive coolant from at least one of the IEM cooling jacket outlet and the on/off valve;a transmission heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an engine oil heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an exhaust gas recirculation cooler configured to receive coolant form the on/off valve and configured to expel coolant to the radiator;an intercooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator;a turbocharger cooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator; andwherein the on/off valve is configured to expel coolant to one of the fourth multi-port flow control valve, the exhaust gas recirculation cooler, the intercooler, and the turbocharger cooler. 10. The engine thermal management system of claim 1 wherein the engine head cooling jacket and the engine block cooling jacket receives coolant directly from the coolant pump, and the IEM cooling jacket receives coolant from the engine head cooling jacket and through metering of the coolant received by the engine head cooling jacket from the coolant pump. 11. The engine thermal management system of claim 10 wherein the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket, the second flow control valve further configured to transmit coolant to at least one of the radiator, the heater core, and the coolant pump. 12. The engine thermal management system of claim 10 wherein the first plurality of multi-port flow control valves further includes a third flow control valve, such that: the first flow control valve is configured to receive coolant from the engine block cooling jacket and further configured to occupy a closed position and a first open position, such that the first flow control valve expels coolant to the second control valve when occupying the first open position;the second flow control valve is configured to receive coolant from at least one of the engine block cooling jacket via the first flow control valve, the engine head cooling jacket, and the IEM cooling jacket via the third flow control valve, the second flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the second flow control valve expels coolant to the coolant pump when occupying the first open position and expels coolant to the radiator when occupying the second open position; andthe third flow control valve is configured to receive coolant from the IEM cooling jacket the third flow control valve further configured to to occupy a closed position, a first open position, and a second open position, such that the third flow control valve expels coolant to the heater core when occupying the first open position and expels coolant to the second flow control valve when occupying the second open position. 13. The engine thermal management system of claim 12 wherein the system further comprises: a second plurality of flow control valves, including at least one on/off valve and a fourth multiport flow control valve, the on/off valve configured to receive coolant from the coolant pump, the fourth multi-port flow control valve configured to receive coolant from at least one of the IEM cooling jacket outlet and the on/off valve;a transmission heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an engine oil heat exchanger configured to receive coolant from the fourth multi-port flow control valve and expel coolant to the radiator;an exhaust gas recirculation cooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator;an intercooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator;a turbocharger cooler configured to receive coolant from the on/off valve and configured to expel coolant to the radiator; andwherein the on/off valve is configured to expel coolant to one of the fourth multi-port flow control valve, the exhaust gas recirculation cooler, the intercooler, and the turbocharger cooler. 14. A method of thermal management for an automotive engine comprising the steps of: actuating, via at least one control module, a plurality of flow control valves to occupy a closed position after the engine is started;signaling, via the at least one control module, a coolant pump to circulate a coolant, when the coolant in the engine reaches a predetermined temperature;selectively directing, via the at least one control module, coolant flow from the coolant pump to each of an engine block cooling jacket, an engine head cooling jacket, and an Integrated Exhaust Manifold cooling jacket;actuating, via the at least one control module, at least one of the first plurality of flow control valves to occupy an open position, when the engine reaches a predetermined temperature; andselectively distributing, via the at least one control module, coolant flow through the first plurality of flow control valves to at least one of a radiator, a heater core, and the coolant pump, wherein coolant flows through each one of the plurality of flow control valves independently of each of the other ones of the plurality of flow control valves. 15. The method of claim 14 wherein the plurality of flow control valves includes: a first flow control valve configured to receive coolant from the engine block cooling jacket and further configured to occupy a closed position and a first open position, such that in the first open position the first flow control valve expels coolant to a third flow control valve;a second flow control valve configured to receive coolant from each of the first flow control valve and the engine head cooling jacket, the second flow control valve further configured to occupy a closed position, a first open position, and a second open position, such that the second flow control valve expels coolant to the coolant pump in the first open position and expels coolant to the radiator in the second open position; andthe third flow control valve configured to receive coolant from the IEM cooling jacket and further configured to occupy a closed position, a first open position, and a second open position, such that the third flow control valve expels coolant to the heater core in the first open position and expels coolant to each of the heater core and the second flow control valve in the second open position. 16. The method of claim 15 wherein coolant is selectively distributed to the radiator to cool the engine, via the second flow control valve occupying the second open position. 17. The method of claim 15 wherein coolant is selectively distributed to the heater core to warm the passenger compartment via the third flow control valve occupying the first open position; and wherein coolant is selectively distributed back to the coolant pump via the heater core and via the second flow control valve occupying the first open position. 18. The method of claim 16 further comprising the steps of: selectively distributing coolant from an on/off valve to each of one of a second plurality of flow control valves, an exhaust gas recirculation cooler, an inter-cooler, and a turbocharger cooler, when engine load is increased, wherein the on/off valve receives coolant directly from the coolant pump;selectively distributing coolant from one of the second plurality of flow control valves to a transmission heat exchanger and an engine oil heat exchanger, when engine load is increased; anddistributing coolant from the transmission heat exchanger, the engine oil heat exchanger, the exhaust gas recirculation cooler, the intercooler, and the turbocharger cooler to the radiator.
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이 특허에 인용된 특허 (9)
Itakura Masato (Toyota JPX), Cooling system controller for internal combustion engines.
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Braun,Marco; Burckhardt,Christoph; Haas,Michael; L체tze,Roland; M체ller,Alexander; Reusch,Michael; Springer,Ulrich; Gregory,Jens von, Method for controlling the heat in an automotive internal combustion engine.
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