Patent Application
20140000536
The present teachings generally include a powertrain cooling system and a method for cooling a powertrain.
Rapid warm-up of engine coolant, engine oil and transmission oil after a cold start can improve vehicle fuel economy. A cold start is a start-up of the vehicle when the vehicle has not been running and the engine and transmission are relatively cold. Engine warm-up is especially challenging for diesel and hybrid applications, as less fuel is burned.
A powertrain cooling system is configured to allow rapid warm-up of powertrain components and fluids, improving fuel economy by reducing frictional losses. The powertrain cooling system includes a coolant pump and a plurality of coolant flow passages. A first three-position valve is operatively connected with an outlet of the coolant pump and has a first, a second, and a third position to at least partially establish different coolant flow modes through the coolant flow passages. Coolant flow from the coolant pump is blocked from both the cylinder head and the engine block in a first of the coolant flow modes when the three-position valve is in the first position. Coolant flow from the coolant pump is provided to the cylinder head and is blocked from the engine block in a second of the coolant flow modes when the three-position valve is in the second position. Coolant flows from the coolant pump to the engine block and from the engine block to the cylinder head in a third of the coolant flow modes when the three-position valve is in the third position.
Accordingly, warming of the cylinder head and the engine block can be separately controlled. For example, a controller can be operatively connected to the first three-position valve and to temperature sensors. A first temperature sensor can be positioned in thermal communication with the cylinder head and with the controller to indicate a cylinder head temperature. A second temperature sensor can be positioned in thermal communication with the engine block and operatively connected to the controller to indicate an engine block temperature. The controller can be configured to (i) place the first three-position valve in the first position when the first temperature sensor indicates the cylinder head temperature is less than a first predetermined temperature, (ii) place the first three-position valve in the second position when the first temperature sensor indicates that the cylinder head temperature is greater than the first predetermined temperature and the engine block temperature is less than a second predetermined temperature; and (iii) place the first three-position valve in the third position when the first temperature sensor indicates that the engine block temperature is greater than the second predetermined temperature. The cylinder head can thus be cooled prior to cooling of the engine block.
Heating and cooling of the transmission and engine oils can also be controlled by the control system with the use of heat exchangers and a second three-position valve. An engine heat exchanger can be positioned in thermal communication with engine oil in the engine block. A transmission heat exchanger can be placed in thermal communication with transmission oil in the transmission. A second three-position valve can be positioned in the coolant flow passages downstream of the engine block in the coolant flow, operatively connected with the controller. Coolant flow is provided to the engine heat exchanger and is blocked from the transmission heat exchanger when the second three-position valve is in a first position. Coolant flow is provided to the transmission heat exchanger and is blocked from the engine heat exchanger when the second three-position valve is in a second position. Coolant flow is provided to both of the engine heat exchanger and the transmission heat exchanger when the second three-position valve is in the third position.
Optionally, an exhaust heat recovery device heat exchanger (EHRDHE) can be positioned at least partially within the exhaust system and in thermal communication with the coolant flow in the coolant flow passages upstream of the second three-position valve. A bypass valve that has a heat exchange position and a bypass position is operable to direct exhaust flow through the EHRDHE in the heat exchange position and to bypass the EHRDHE in the bypass position. The bypass valve is controlled to be in the heat exchange position when the second three-position valve is in the first position and when the second three-position valve is in the second position, and is controlled to be in the bypass position when the second three-position valve is in the third position.
The powertrain cooling system may also include a radiator operatively connected to the coolant flow passages. A radiator valve may be positioned in the coolant flow passages between the radiator and an inlet of the water pump. The radiator valve is configured to have an open position than permits coolant flow through the radiator and a closed position that prevents coolant flow through the radiator. The radiator valve may be operatively connected to the controller and controlled to be in the closed position in the first and the second of the coolant flow modes. The radiator valve can be controlled to be in the open position in the third coolant flow mode when the second three-position valve is in the third position and the coolant temperature is indicative of the engine oil temperature and the transmission oil temperature being greater than a predetermined maximum oil temperature. The predetermined maximum oil temperature is greater than the predetermined oil temperature.
The powertrain cooling system can also be controlled to assist with heating of the vehicle passenger compartment. Specifically, a passenger compartment heater can be positioned in thermal communication with the coolant flow in the coolant flow passages downstream of the cylinder head and upstream of the second three-position valve. Heat from the coolant is thus used to heat the passenger compartment via the passenger compartment heat exchanger.
A method of cooling a powertrain that has an engine with a cylinder head and an engine block includes controlling a first three-position valve to a first position to block coolant flow to the engine when a temperature of the cylinder head is less than a first predetermined temperature. The first three-position valve is positioned upstream of the engine and downstream of a coolant flow pump. The method further includes controlling the first three-position valve to a second position to direct the coolant flow to the cylinder head and block coolant flow from the engine when the temperature of the cylinder head is greater than the first predetermined temperature and a temperature of the engine block is less than a second predetermined temperature. Under the method, the first three-position valve is controlled to a third position to direct the coolant flow to both the cylinder head and the engine block when the temperature of the engine block is greater than the second predetermined temperature.
The above features and advantages and other features and advantages of the present teachings are readily apparent from the following detailed description of the best modes for carrying out the present teachings when taken in connection with the accompanying drawings.
Referring to the drawings, wherein like reference numbers refer to like components throughout the several views,
The engine 16 has an exhaust system 24 that includes an exhaust manifold 26 mounted to the cylinder head 20. Exhaust gas is discharged from the engine 16 through the exhaust manifold 26 and an exhaust pipe 28 operatively connected thereto. An exhaust heat recovery device heat exchanger (EHRDHE) 30 is positioned in thermal communication with coolant flow in the cooling system 14 and is selectively in thermal communication with the exhaust gas in the exhaust pipe 28 as explained herein. A bypass valve 32 is controllable between two different positions. In a heat exchange position, exhaust gas flows through the EHRDHE 30. When the bypass valve 32 is in a second, bypass position, the exhaust gas flows through a bypass conduit 34 connected to the exhaust pipe 28 to bypass the EHRDHE 30.
The powertrain cooling system 14 is provided to regulate the flow of coolant and to regulate exhaust flow in order to provide warm-up of the components and fluids of the powertrain 12 in the priority most beneficial for fuel efficiency, and then maintain optimal temperatures. The powertrain cooling system 14 includes multiple coolant flow passages 50A, 50B, 50C, 50D, 50E, 50F, 50G, 50H, 50J, 50K, 50P, 50Q, 50R, and 50S through which coolant can be pumped by a pump 52, referred to herein as a water pump or a coolant pump. The coolant flow passages 50A, 50B, 50C, 50D, 50E, 50F, 50G, 50H, 50J, 50K, 50P, 50Q, 50R, and 50S may be conduits or flexible or rigid tubing, or may be bored, drilled, cast or otherwise formed passages in any vehicle component. The pump 52 has an inlet 52A and an outlet 52B. The pump 52 may be driven by the engine 16. Coolant flow through the passages 50A, 50B, 50C, 50D, 50E, 50F, 50G, 50H, 50J, 50K, 50P, 50Q, 50R, and 50S is controlled by multiple valves 54, 56, 58 under the control of a controller 60 to establish different cooling flow modes. The position of the bypass valve 32 is also controlled by the controller 60.
The valve 54 is referred to as a first three-position valve. The valve 54 has an inlet 54A connected to the outlet 52B of the pump 52 by the passage 50A, a first outlet 54B connected to the cylinder head 20 by the passage 50B, and a second outlet 54C connected to the engine block 18 by the passage 50C. The valve 54 is downstream of the pump 52 and upstream of the engine 16 in the direction of coolant flow through the passages 50A, 50B, 50C. The direction of coolant flow, when coolant is permitted to flow by the valve 54, is indicated by arrow heads at the ends of the respective passages 50A-50S. As used herein, a first component is “downstream” of a second component if coolant flows to the first component from the second component during a single circulation loop of the flow circuit, with the flow circuit beginning at the outlet 52B of the pump 52. A first component is “upstream” of a second component if coolant flows from the first component to the second component in a single circulation loop of the flow circuit with the flow circuit beginning at the outlet 52B of the pump 52.
The valve 54 is a rotary valve in the embodiment shown, but may be any type of valve having at least three positions and capable of establishing the flow modes described herein. The valve 54 has an internal movable member 55 that can be controlled by the controller 60 to establish three different positions, as shown in
Similarly, the valve 56 is a three-position valve and has an inlet 56A, a first outlet 56B and a second outlet 56C. The inlet 56A is connected to the EHRDHE 30 by the coolant passage 50H of
The valve 56 is a rotary valve but may be any type of valve having at least three positions and capable of establishing the flow modes described herein. The valve 56 has an internal movable member 55A that can be controlled by the controller 60 to establish three different positions as shown in
Referring again to
In an alternative embodiment, the bypass valve 32 could be any self-regulating valve that opens and closes automatically in response to temperature. For example, the bypass valve 32 could open in response to an actuator, such as a thermal wax, which is in thermal communication with the coolant and adjusts the valve opening based on the temperature of the coolant and expansion or contraction of the wax which is in contact with the bypass valve 32. The bypass valve 32 could be configured to open automatically at a predetermined coolant temperature.
The radiator valve 58 has a first inlet 58A, a second inlet 58B and an outlet 58C. The outlet 58C of the valve 58 is connected to the inlet 52A of the pump 52 by the passage 50R. An internal member 59 is movable, in response to control signals from the controller 60, from a first position, shown in
In an alternative embodiment, the radiator valve 58 could be any self-regulating valve that opens and closes automatically in response to temperature. For example, the internal member 59 could open in response to an actuator, such as a thermal wax, which adjusts the valve opening based on the temperature of the coolant and expansion or contraction of the wax which is in contact with the movable member 59. The valve 58 could be configured so that the internal member 59 opens automatically at a predetermined coolant temperature.
The powertrain cooling system 14 also includes multiple temperature sensors operatively connected to the controller 60 to provide current temperature conditions in the powertrain 12. For example, a first temperature sensor 80 is mounted to, or in, or is otherwise operatively connected to the cylinder head 20 such that the sensor 80 is in thermal communication with the cylinder head 20 and can provide sensor signals to the controller 60 indicative of a cylinder head temperature. The electrical wiring connecting the sensor 80 to the controller 60 is not shown for purposes of clarity in the drawings.
A second temperature sensor 82 is mounted to, or in, or is otherwise operatively connected to the engine block 18 such that the sensor 82 is in thermal communication with the engine block 18 and can provide sensor signals to the controller 60 indicative of an engine block temperature. The electrical wiring connecting the sensor 82 to the controller 60 is not shown for purposes of clarity in the drawings.
A third temperature sensor 84 is mounted to, or in, or is otherwise operatively connected to the oil pan 85 mounted to the engine block 18 such that the sensor 84 is in thermal communication with engine oil that collects in the oil pan 85 and can provide sensor signals to the controller 60 indicative of an engine oil temperature. The electrical wiring connecting the sensor 84 to the controller 60 is not shown for purposes of clarity in the drawings.
A fourth temperature sensor 86 is mounted to, or in, or is otherwise operatively connected to the transmission 22 such that the sensor 86 is in thermal communication with transmission oil within the transmission 22 and can provide sensor signals to the controller 60 indicative of a transmission oil temperature. The electrical wiring connecting the sensor 86 to the controller 60 is not shown for purposes of clarity in the drawings.
In the first cooling flow mode of
When the first temperature sensor 80 indicates that the temperature of the cylinder head 20 is greater than a first predetermined temperature, and the second temperature sensor 82 indicates that the temperature of the engine block 18 is less than a second predetermined temperature, the controller 60 will establish a second cooling flow mode by placing the valve 54 in the second position of
With the valve 54 in the second position, pumped coolant flows through the cylinder head 20, to the heater 23, through the EHRDHE 30, and through the engine heat exchanger 62 through passages 50A, 50B, 50E, 50F, 50G, 50H, 50J, 50K and 50R. In this flow mode, the coolant will extract heat from the cylinder head 20, provide heat at the heater 23, pickup additional heat in the EHRDHE 30, and provide heat at the engine heat exchanger 62 to heat the engine oil in the oil pan 85. The transmission oil is not initially heated by the transmission heat exchanger 64, as coolant does not flow to the transmission heat exchanger 64 at the outset of the second cooling flow mode. However, once the engine oil is heated to a predetermined temperature, the second three-position valve 56 can be controlled to move to the second position of
During the second cooling flow mode, the controller 60 continues to receive sensor signals from the temperature sensors indicative of sensed temperature conditions as described above. When the second temperature sensor 82 indicates that the temperature of the engine block 18 is greater than the second predetermined temperature, the controller 60 places the valve 54 in the third position, so that coolant flows to the engine block 18 and then to the cylinder head 20 in a U-formation through the passages 50D and 50E. The internal passages in the engine block 18, represented by passage 50D, are in continuous fluid communication with the internal passages of the cylinder head 20, represented by passage 50E creating a U-formation. It should be appreciated that the internal passages in the engine block 18 and the internal passages in the cylinder head 20 may be configured to be in fluid communication with one another in formations other than a U-formation. That is, the passages 50D, 50E may be configured in other than a U-formation.
When the valve 54 is in the second position of
During the third cooling flow mode, the valve 56 is controlled to establish staged heating of the engine oil and the transmission oil by moving between the first and second positions.
Exhaust heat recovery and coolant flow to the engine heat exchanger 62 and the transmission heat exchanger 64 continues until oil temperatures are consistent with maximum frictional benefits. Once the temperature sensors 84, 86 indicate that a predetermined maximum oil temperature at which maximum frictional benefits are achieved has been reached, a fourth cooling flow mode is established as shown in
A method of cooling a powertrain 12 that has an engine 16 with a cylinder head 20 and an engine block 18 thus includes controlling a first three-position valve 54 to a first position to block coolant flow to the engine block 18 when a temperature of the cylinder head 20 is less than a first predetermined temperature. The method further includes controlling the first three-position valve 54 to a second position to direct the coolant flow to the cylinder head 20 and block coolant flow from the engine block 18 when the temperature of the cylinder head 20 is greater than the first predetermined temperature and a temperature of the engine block 18 is less than a second predetermined temperature The method then includes controlling the first three-position valve 54 to a third position to direct the coolant flow to both the cylinder head 20 and the engine block 18 when the temperature of the engine block 18 is greater than the second predetermined temperature.
The method may include controlling a second three-position valve 56 that is downstream of the engine 16 to a first position to direct the coolant flow to an engine heat exchanger 62 when an engine oil temperature is less than a predetermined engine oil temperature. The second three-position valve 56 can then be controlled to a second position to direct the coolant flow to a transmission heat exchanger 64 when a transmission oil temperature is less than a predetermined transmission oil temperature and the engine oil temperature is greater than the predetermined engine oil temperature. The method may then include controlling the second three-position valve 56 to a third position to direct the coolant flow to both the engine heat exchanger 62 and the transmission heat exchanger 64 when the transmission oil temperature is greater than a predetermined transmission oil temperature and the engine oil temperature is greater than the predetermined engine oil temperature. The predetermined transmission oil temperature may be the same as the predetermined engine oil temperature.
Additionally, an exhaust heat recovery bypass valve 32 may be controlled under the method to direct engine exhaust so that it is in thermal communication with the coolant flow when the second three-position valve 56 is in the first position or in the second position. The exhaust heat recovery bypass valve 32 may be controlled so that the engine exhaust bypasses thermal communication with the coolant flow when the second three-position valve 56 is in the third position. A radiator valve 58 may be positioned in the coolant flow downstream of the engine heat exchanger 62 and the transmission heat exchanger 64, upstream of an inlet 52A of the coolant pump 52, and downstream of a radiator 70. Under the method, the valve 58 may be controlled to maintain a closed position in which coolant flow from the radiator 70 is blocked from the inlet 52A of the pump 50, shown in
While the best modes for carrying out the many aspects of the present teachings have been described in detail, those familiar with the art to which these teachings relate will recognize various alternative aspects for practicing the present teachings that are within the scope of the appended claims.
