DE102011114110A1 - Method for controlling hybrid machine-drive train, involves monitoring driving speed of motor when driving torque is delivered and observed by motor - Google Patents

Abstract

The method involves monitoring driving speed of a motor (20) when driving torque is delivered and observed by the motor, where load of the motor is determined based on the driving torque and the driving speed of the motor. A control mode for another motor (62) is selected based on the load of former motor so that the motors and a machine decoupler are controlled according to the control mode.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 61 / 388,555, filed Sep. 30, 2010, which is incorporated herein by reference.

TECHNICAL AREA

This disclosure relates to the control of a hybrid powertrain.

BACKGROUND

The statements in this section merely provide background information related to the present disclosure. Accordingly, such statements are not intended to constitute acknowledgment of any prior art.

Hybrid power train powertrains are known that include multiple torque generating devices. For example, a powertrain may include an internal combustion engine and an electric motor, and the engine and engine may be controlled to increase overall vehicle efficiency, for example, by using the engine in an engine-efficient operation Machine in an operation that is efficient for the machine is used, both devices are used to cooperatively provide torque when such operation is efficient, and the engine is used to power an energy storage device, for example during braking of the vehicle, or recover by pulling torque from the machine.

In an exemplary embodiment, the engine and the engine each provide torque to the powertrain. In another exemplary embodiment, the engine applies torque to the engine, and the engine in turn supplies torque to the remainder of the powertrain.

Shutting down the engine when not in use saves fuel that would be consumed by otherwise idling or running the engine at low speed. When the engine is off, a shaft leading from the engine to the driveline will either stop spinning, requiring the rest of the driveline to settle on the non-moving shaft, or the rest of the powertrain will have a torque to turn the machine off, overcoming the torque (due to friction, cylinder pumping forces, etc.) required to turn the machine. A clutch device may be employed between the engine and the remainder of the powertrain to allow the engine to be shut down and stopped while the remainder of the driveline continues to function.

Clutch devices or clutches are used to selectively connect or disconnect shafts capable of transmitting torque. Clutches can be hydraulically operated. Exemplary switching between states controlled by a pair of clutches requires one clutch to be relieved, allowing two shafts that were previously coupled to circulate freely of each other, and then load another clutch, two Waves that were previously decoupled or free to rotate relative to each other. Hydraulically actuated clutches often include clutch plates that are spring biased to a decoupled home position wherein hydraulic pressure applied to a piston applies pressure that overcomes the bias of the spring to bring the plates into a coupled position.

Machines may include a dedicated starter motor that provides torque to the machine to turn on the machine during takeoff. Torque to start the engine may be pulled by the powertrain or the associated powertrain engine. A hybrid powertrain may include multiple engines, where one engine may be used to provide torque to the rest of the powertrain and thus propel one vehicle while the other engine may be used to start the engine.

SUMMARY

A powertrain includes a first electric motor coupled to an engine having a ratio changing means and a second motor selectively coupled to the engine through a engine disconnect clutch, the second motor further coupled to an input shaft of a transmission. A method of controlling the powertrain includes monitoring a propulsion torque provided by the second engine, monitoring a rotational speed of the second engine, determining a condition of the second engine based on the propulsion torque and the rotational speed of the second engine, a control mode for the first motor is selected on the basis of the condition of the second motor, and the first motor, the second motor, and the engine disconnect clutch are controlled on the basis of the control mode.

BRIEF DESCRIPTION OF THE DRAWINGS

One or more embodiments will now be described by way of example with reference to the accompanying drawings, in which:

1 illustrates an exemplary hybrid powertrain according to the present disclosure;

2 an exemplary control module for performing a flying engine start illustrated in accordance with the present disclosure;

3 an exemplary flying engine start, which includes the use of torque from a first and a second engine, illustrated in accordance with the present disclosure;

4 Torque from a first motor and torque from a second motor cooperatively used to provide a desired torque illustrated in accordance with the present disclosure; and

5 illustrate an exemplary process for performing a flying engine start in accordance with the present disclosure.

DETAILED DESCRIPTION

Referring now to the drawings, in which the drawings are provided solely for the purpose of illustrating certain example embodiments and not for the purpose of limiting the same 1 an exemplary hybrid powertrain. The powertrain 5 includes a machine 10 , a first electric motor 62 , a second electric motor 20 , an energy storage device 30 and a transmission device 40 , The first electric motor 62 can directly with the crankshaft of the machine 10 be connected via a gear ratio changing means, so that a circulation ratio of the motor 62 can be changed relative to the crankshaft. Many gear ratio changing means are known in the art, an exemplary embodiment comprising a pulley drive means. A machine output shaft 50 is with a motor input shaft 52 by a coupling device 54 connected. In one embodiment, the coupling device 54 referred to as a machine-disconnect clutch (EDC), wherein selective activation of the clutch either enables the engine 10 Torque to the engine 10 and the input shaft of the transmission 40 supplies, or it allows the machine 10 regardless of the engine 20 revolves or stops. When the coupling device 54 is in an engaged state and there is no slippage within the clutch device, the engine output shaft is running 50 at the same rate as the engine input shaft 52 around, and torque can be between the machine 10 and the engine 20 be transmitted. When the coupling device 54 is disengaged or in a disengaged state, the machine can 10 at a different rate to the engine 20 turn or is off the engine 20 disconnected, or the machine 10 can be switched off without the operation of the engine 20 to influence. When the coupling device 54 is disengaged, the engine can 20 used to torque to the output shaft 56 through the transmission 40 regardless of whether the machine 10 is in a working state or a disconnected state. The machine 10 is illustrated in such a way that it directly with the engine 20 through waves 50 and 52 and coupling device 54 connected is. The coupling device 54 In one exemplary embodiment, a hydraulically actuated clutch may be controlled at which hydraulic pressure may be varied to vary torque capacity. and varying levels of slippage across the clutch means 54 be enabled and controlled. It will be appreciated that a number of powertrain configurations are possible, including, for example, the use of planetary gear sets to alter the manner in which the engine is operated 10 and the engine 20 interact and torque to the powertrain 5 deliver. The coupling device 54 can exist between two waves, as in 1 is illustrated. Other embodiments are contemplated, for example with a transmission 40 comprising a brake clutch which is connected to an element of a planetary gear set and controls how torque through the planetary gear set on the output shaft 56 is transmitted. In another embodiment, multiple engines may provide torque to the output through the transmission while one or both are connected to the engine. A number of exemplary powertrain embodiments and configurations are contemplated for use with the present invention, and the disclosure is not intended to be limited to the particular exemplary embodiments set forth herein.

Control modules can control the operation of the machine 10 , of the motor 20 , of the motor 62 , the transmission 40 and the coupling device 54 Taxes. Controllers may be employed by the control modules, which synchronize the operation of the various devices to maintain the driveability of the overall driveline. Control module, module, controller, controller, controller, processor, and similar terms mean any of or various combinations of one or more of an application specific integrated circuit / application specific integrated circuit (ASIC), electronic circuit (s), central processing unit (s) , (preferably a microprocessor / microprocessors) and associated memory and storage means (read-only, programmable read-only, random access, hard disk, etc.) executing one or more software or firmware programs or routines, a combinatorial logic / combinational logic Circuits, a sequential logic circuit / sequential logic circuits, an input / output circuit and an input / output device / input / output circuits and input / output devices, a geeigne signal conditioning and buffering circuit and other components to provide the described functionality. Software, firmware, programs, instructions, routines, code, algorithms, and similar expressions mean any controller-executable instruction sets that include calibrations and look-up tables. The control module has a set of control routines that are executed to provide the desired functions. Routines are executed, such as by a central processing unit, and are operable to monitor inputs from detectors and other networked control modules and to perform control and diagnostic routines to control the operation of actuators. Routines may be executed on the basis of events or at regular intervals, for example every 3.125, 6.25, 12.5, 25 and 100 milliseconds, during ongoing machine and vehicle operation.

The operation of the engines 20 and 62 can be selected according to a number of desired functions or control modes. The powertrain may operate in a parallel hybrid mode in which torque from the engine 10 on the engine 20 is transmitted and torque from the engine 20 that includes torque coming from the machine 10 is delivered to the input shaft of the transmission 40 is transmitted. Control modes of the first motor 62 may include a driving mode in which torque from the engine 62 the machine 10 is supplied, and in which coupling device 54 is engaged so that torque coming from the engine 62 is delivered, increases torque, which is on the input shaft of the transmission 40 is applied. Another control mode of the first motor 62 may include a passive mode in which the engine is allowed to freely revolve, leaving the engine 10 Torque with only minimal inertia load through the motor 62 can generate. The powertrain may also operate in a series hybrid mode in which the engine 10 is used to generate electrical power from the engine 20 Can be used to transmit torque to the input shaft of the transmission 40 to create. In the series hybrid mode or the parallel hybrid mode, the first motor 62 working in a generator mode, in which torque from the machine 10 used to be the first engine 62 to turn, and resulting electrical energy coming from the first motor 62 is generated, used to power the second electric motor 20 to deliver. Additionally or alternatively, the first motor 62 operate in a battery recharge mode, in which torque from the engine 10 used to be the first engine 62 to turn, and resulting electrical energy coming from the first motor 62 is used to increase a state of charge of an energy storage device, which is used by the drive train. In the parallel hybrid mode, either a first-to-second engine torque-generating branch or a first-to-second engine torque-regenerative branch may be determined in accordance with methods disclosed herein to allocate torque between the engines. According to an exemplary embodiment, a total torque that is between the engine, either propulsion torque or braking torque, is known and based on the speed of each of the motors, the efficiency of each engine is determined over a range of torque values, and the total torque is determined based on the highest or preferred overall efficiency of both Split engines.

In addition to being used in the modes associated with parallel or in-line hybrid modes of operation, the engine may 62 be used for other functions. For example, the engine can 62 be used to perform an engine start or a flying engine start, in which the vehicle is moving and the machine must be brought into a state in which the coupling device 54 can be indented. The first engine 62 may include an engine start mode with only the first engine in which the engine 62 a total torque that is required to the machine 10 from a stopped state to start delivering. According to one embodiment, an engine start mode may be selected with only the first engine based on comparing a propulsion torque provided by the second engine with a maximum torque of the second engine and determining that the second engine has insufficient surplus capability to help with the engine start. Another control mode of the first motor 62 may include an engine start mode with cooperating two engines in which torque from the engine 62 and torque generated by the coupling device 54 is used to start the machine. A cooperative engine start mode may similarly include a flying engine start of a flying engine start mode with cooperating two engines. A flying engine start mode with cooperating two engines may be selected, for example, by comparing a propulsion torque provided by the second engine with a maximum torque of the second engine and determining that the second engine has sufficient surplus capability to start the engine to help. Another control mode of the first motor 62 may include an energy recovery mode in which torque generated by the clutch device 54 is transmitted, for example reaction torque, in response to engine 62 Applying brake torque to slow down the input shaft and attached driveline is used to drive the first engine 62 to turn, and resulting electrical energy coming from the first motor 62 is generated, used to power the second electric motor 20 supply and / or recharge an energy storage device. A number of control modes for the first engine 62 is contemplated and the disclosed methods are not limited to the specific examples herein.

The selection of a control mode for the first motor 62 may be made based on a number of factors including the operation of the powertrain and driver commands, such as an operator torque request indicated by an accelerator or brake pedal position. In some circumstances, a maximum or defined capacity of the first engine 63 and the second motor 20 required. For example, the second engine delivers 20 when operating as a series hybrid, a speed and torque defined by the desired operation of the transmission and the attached driveline, and the first motor 62 works in a selected state on the basis of that machine 10 at a selected condition works to get through the engine 62 to generate electrical energy. However, under other circumstances, the first engine will become 62 and the second engine 20 cooperatively controlled to provide a desired torque that is less than a sum of the maximum torques that the motors can produce. In one example, to generate braking torque, each of the first engine may be 62 and the second engine 20 operate in an energy recovery mode, wherein each motor supplies a portion of the total desired braking torque. In another example, each one of the first engine 62 and the second engine 20 in the cooperative engine start mode provide a portion of the desired engine torque.

In some modes, the first engine can 62 and the second engine 20 each assigned a part of a function, and the motors together provide the necessary capacity for the function. For example, at a machine start, a required turn-on torque for the engine T _{E_CRANK may be shared} between the engines. In another example, it may be preferable for one of the motors to deliver all the required cranking torque. It is a method disclosed to a control mode of the first motor 62 to select and a total required torque between the first motor 62 and the second engine 20 based on the operation or condition of the second motor 20 allot.

A number of parameters can be used to define a condition of the second motor 20 to investigate. Parameters representing the condition of the second motor may include torque, speed, and engine efficiency.

Second motor torque may be used to determine a mode for the first motor and torque for the first motor 62 and the second engine 20 allot. Torque requirements of the second motor 20 can the allocation of torque between engine 62 and engine 20 influence. For example, it may be necessary for the engine 20 some or all of the required torque of the input shaft of the transmission 40 based on the required output torque. The allocation of torque or the use of different modes of the first engine 62 can be made on the basis of torque, for example, by comparison with a maximum torque of the second motor 20 , According to a method of using the engine 20 to get a flying start of the machine 10 To carry out the control of the engine 20 a constant buffer against the maximum torque of the engine 20 include, wherein a torque that the engine 20 the input shaft can supply, is constantly reduced, in the case that the machine 10 needed a torque buffer to start immediately. If that from the engine 20 generated torque to supply the required torque to the transmission is low, so that maintaining the buffer, which is required to be able to supply a cranking torque at any time, does not affect the ability of the engine, the required torque to to deliver the gearbox, then the engine can 20 be suitable for most or all of that to start the machine 10 supply required cranking torque. If that from the engine 20 generated torque to deliver the required torque to the transmission is high, so that maintaining the buffer, which is required to be able to supply a cranking torque at any time can affect the ability of the engine, the required torque to the To provide transmission, or adversely affects a desired torque reserve, which is advantageous to secure, if the driver requests additional torque, then the engine 20 be excluded, some or all of that to start the machine 10 supply required cranking torque. In one embodiment, the first engine 62 in a mode of increased contribution of the first engine, for example, a flying engine startup mode with increased contribution of the first engine, based on limited capabilities of the second engine to provide immediate torque. In one embodiment, a flying engine startup mode with the first engine's contribution may be used to maintain the second engine's ability to provide a desired output torque or desired output torque or maintain an ability of the vehicle to maintain a desired maximum vehicle speed. The operation of an electric motor may include a torque limited range in which the engine is limited to supply no more than a maximum torque, and a power limited range in which the engine provides torque that it can deliver at the speed at which it is driven circulates, needs to balance. A determination based on engine speed and engine torque may be made as to whether or how much additional torque the engine can efficiently deliver. Based on this determination, a mode for the first motor can be selected. Further, a determination may be made to avoid allocating torque to an engine that causes the engine to operate inefficiently with respect to the power limited operation. For example, if a potential or candidate control mode for the first engine is identified, a determination may be made as to whether the candidate mode would cause the second engine to operate inefficiently, such as caused by the engine being extended into a power limited range ,

Similarly, a speed of the engine 20 the allocation of torque between the engine 62 and the engine 20 influence. If in one example the second engine 20 Torque to the input shaft of the transmission 40 provides while the vehicle or powertrain is operating in a creep mode (ie, progressing under low forward speed power), then the speed of the engine may increase 20 be too low that the machine 10 with the engine 20 synchronized, which causes the machine to go below a minimum speed. In such case, the operation may be in a mode that requires torque between the machine 10 and the second engine 20 For example, it may be a controlled slippage of the engine disconnect clutch 54 require, or be impossible. Therefore, either a flying engine start mode with only the first engine or an operation of the powertrain in a series hybrid mode where the first engine is operating in a generator mode may be preferred when the vehicle is operating in a creep mode. In another embodiment, the second motor 20 used only briefly to provide an initial part of the torque that is necessary to the machine 10 initially set in motion, the engine disconnect clutch 54 with controlled slip, and then quickly switch to a first flying engine start mode with only the first engine.

The efficiency of operating a particular electric motor at various torques and speeds is a potentially known property of an electric motor, for example, quantifying electrical power consumed or generated for a given engine torque. which may be used as a parameter to determine a mode for the first motor and to allocate torque between the first motor and the second motor. The efficiency of the second motor may be analyzed, or a comparison of the efficiency of two electric motors may be made. For example, if energy recovery or braking torque has to be allocated between the two engines, if the first engine 62 a smaller capacity than the second engine 20 can, the engine can 20 be more efficient than motor at a given speed and torque in the energy recovery mode 62 , In such an example, that of the engine 20 generated braking torque can be maximized at the higher efficiency before a remaining portion of the braking torque to the engine 62 is allocated. In another exemplary embodiment, a series or parallel hybrid mode may be selected based on a comparison of the resulting efficiencies of the modes. In another example embodiment, it may be preferable to maintain control of the speed of a fully or partially disconnected engine through the braking event so that operation of the vehicle can be quickly restored to a normal propulsion mode under engine power when the braking mode abruptly ends. Under such a condition, the entirety of the energy recovery can be performed by the second engine, with the first engine operating in a recirculating-machine control mode.

Desirable behavior of the vehicle may be used as a parameter to determine a mode for the first motor and to allocate torque between the first motor and the second motor. For example, a desired maximum vehicle speed or a desired acceleration capability of the vehicle may be protected, with the mode selection and allocation of torque between the engines preserving the ability of the vehicle to behave as desired. In one embodiment, maintaining the vehicle's ability to behave may include selecting a mode and allocating torque based on a desired available output torque, such as a current output torque and / or output torque buffer that needs to be preserved; includes.

Other parameters that illustrate a condition of the second engine or engines may be used to determine a mode for the first engine and the resulting torque allocation between the two engines, including, for example, parameters having driveability concerns or perceptible effects Vehicle acceleration, noise issues, durability concerns for the vehicle components or systems involved and predictable vehicle operation over a foreseeable period of time. In one example, the second engine may be operated in a low torque disturb mode, with any driveability effects minimized, and any other functions such as the operation of a flying engine start fully powered by the first engine. In such an embodiment, the first motor may additionally be used to synchronize the engine with the second engine with minimal torque disturbance. A number of parameters representing a condition of the motors are contemplated, and the disclosure is not limited to the particular embodiments cited.

Motor designs for the first motor 62 and the second engine 20 may include substantially equivalent engines, each capable of providing the same or similar engine torque and speed characteristics. In another embodiment, the motors may be selected for their specific anticipated roles. For example, the second engine 20 a relatively large engine or a high capacity engine capable of delivering all propulsion torque for the powertrain while the first engine 62 may be a relatively small or low-capacity motor, for example, capable of delivering only a portion of the total torque required to crank the engine. Such capacities and associated operating characteristics of the motors may be used to select different modes for the first motor or to limit the selection.

The first engine 62 can with the machine 10 be associated with a gear ratio changing means that allows the first motor 62 at a different speed than the machine 10 can run around. Gear sets or other devices can be used. In one embodiment, a pulley drive means may be used.

The second engine 20 can torque to the input shaft of the transmission 40 deliver while torque through the engine disconnect clutch 54 is transmitted. The drivability can be adversely affected by abruptly engaging a machine disconnect clutch with a motor that already supplies torque to a transmission. The second engine draws based on a motor torque command an amount of power from an associated energy storage device that corresponds to the torque expected by the engine to the transmission. The engagement of the engine disconnect clutch while the engine continues to draw the same amount of power results in the same torque output from the engine being shared between the transmission and the engine. In a desired mode, for example, a parallel hybrid configuration, a torque profile may be determined or estimated to predict how much torque will be transmitted through the engine disconnect clutch. In the example of a flying engine start, a desired engine activation speed profile may be determined for a particular aircraft engine start, such that the expected operation of the engine may be determined through engine startup. Controlling a powertrain by a flying engine start may include determining an engine torque required to provide a desired torque to the transmission, determining an engine torque that will be required by the engine disconnect clutch that provides the necessary cranking torque. Provides torque to the engine to perform the flying engine start, and the engine is controlled by the engine torque, which will be required by the engine disconnect clutch, which provides the necessary torque to the engine, and the engine torque that is required by the target Torque to the gearbox to be summed.

A flying engine start may include an engine that is initially disconnected from the powertrain via a disengaged EDC and does not rotate (ie, zero speed). In the course of a flying engine start, a previously separate engine is accelerated from an initial speed of zero to a speed that is synchronous with a speed of another shaft or to a synchronous speed (N _{e_synch} ), such that one clutch connecting the engine to the other Shaft connects, can be locked and the machine can deliver torque to the rest of the drivetrain. In an embodiment where the clutch adjusts _{engine speed} to an input _speed , the N _{e_synch} value that the engine must adjust is the input _speed . If the speed that needs to be adjusted is a dynamic profile, for example, an accelerating input speed, then N _{e_synch} must be determined based on factors that affect the operation of the powertrain. An example factor is the ability of the machine to accelerate from a stop to a given speed with acceptable parameters. For a given input _{speed profile} and a machine of known characteristics, N _{e_synch} may be _determined by calibration, calculation, modeling, and / or any method sufficient to accurately predict the operation of the engine, clutch, and remainder of the powertrain, and a number of Calibration curves or predictive modifiers can be used for different conditions and operating ranges.

A flying machine start can start the machine 10 and transferring from the designed state to an operating state while the engine is running 20 Torque to the transmission 40 supplies. According to an exemplary embodiment, a flying engine start can be accomplished by coupling means 54 is engaged, eliminating torque from the engine device 20 the machine 10 is fed and the machine 10 is rotated so that the combustion cycle can begin.

In one embodiment, a flying engine start may include applying torque to an engine through an EDC, which may include controlling the EDC, for example, based on a comparison of an actual engine speed with an engine speed profile for the airborne engine start to ensure controllability of the clutch. and includes control of the EDC with a PI curve fit based on a solenoid current and a steady state clutch pressure feedback. Testing, estimating or modeling the EDC clutch pressure by a flying engine start can be used to determine a required engine torque necessary to compensate for engine load on the EDC or an engine compensation torque as the engine rotates. In one embodiment, cranking torque required to revolve the engine, for example, by flying engine start, as determined by testing, estimating, or modeling, may be used to determine or estimate a compensation torque that is required to supply the torque required to revolve the machine. Determining the compensation torque may include using a clutch pressure torque model to estimate a reaction torque in the EDC. In addition, a pressure-torque compensation model may be used to compensate for non-linearity, time delay, and temperature effects present in a hydraulic pressure measurement. In one embodiment, a controlled EDC torque may be controlled based on a feedforward calculation of engine inertia, friction, and compression torque. Machine moment of inertia can be calculated based on a calibrated machine acceleration profile. In one embodiment, propulsion torque may also be determined using a modulated pressure at a Transmission output clutch can be controlled or smoothed. Slipping the transmission output clutch disconnects the downstream driveline from vibrations that occur due to an imperfectly-compensated disturbance during the on-machine engine start event, allowing for slip when torque applied to the transmission output clutch exceeds a selected value.

2 schematically illustrates an exemplary control module for performing a flying engine start, the control module 100 for a flying engine start comprises a summation block 110 that _promotes a motor torque required to drive the _driveline or a propulsion _torque (T _{m_propel} ) 138 and required engine torque necessary to compensate engine _load on the EDC by flying engine start or engine compensation _torque (T _{m_comp} ) 136 sums and a motor torque _command (T _{m_cmd} ) 146 to a motor inverter 120 outputs that controls an associated engine. A control module 100 for a flying engine start additionally a control module 240 for active driveline damping, which is a signal 144 on the basis of reducing torque fluctuation in the output torque to the summation modulus 110 supplies. The control module 100 may receive an input from the engine control module regarding required engine torque generation, or the control module 100 can directly calculate the required engine torque generation.

The illustrated control module 100 for a flying engine start, a number of terms are determined in support of T _{m_comp} 136 , A machine speed profiling module 140 determines a machine _{speed profile} for the flying machine start, which has a target machine _acceleration (N _{edot_ref} ) 108 and a target engine _speed (N _{e_ref} ) 112 includes, based on an actual engine speed 106 and a current output speed of the transmission output or a current output speed 104 , N _{edot_ref} 108 and N _{e_ref} 112 be in an EDC torque control module 150 used to generate an EDC torque control term 116 or to determine a clutch control term. N _{e_ref} 112 , the actual engine speed 106 and the actual engine torque 114 be in an EDC slip control module 160 used to get an EDC torque control term 118 or to determine the clutch control term. Because torque from the second engine 20 with a torque from the first engine 62 may be balanced or subjected to a branch torque command therewith, the EDC torque control module 150 and / or the EDC slip control module 160 include an entrance that defines the balance. Whether the balance input is required by the control calculation depends on the nature of the torque command being shared and how the system is to respond to the control correction of the command. According to an embodiment in which a precise engine speed is controlled by cooperative control of the two engines, the second engine may 20 With a control system used to provide smooth torque transfer to the transmission 40 uphold, and the first engine 62 can be controlled by a controller and receive additional control commands to make fine adjustments to the engine speed. In this example, control commands become the first engine 62 and the second engine 20 controlled by a torque generating branch from the first motor to the second motor, which is determined by methods disclosed herein. By regulating the control of the EDC 54 can be the transmission of changes in torque from that of the first engine 62 on the machine 10 is applied from the influence of torque acting on the transmission 40 is transmitted, filtered. The EDC torque control term 116 and the EDC torque control term 118 be in summation module 220 summed using an EDC torque command 122 is formed. The EDC torque command 122 is based on torque and pressure characteristics of the EDC in the module 170 converted to the EDC print command 124 to investigate. The EDC print command 124 comes with an actual EDC pressure 128 in the pressure regulation module 180 compared with closed loop. The actual EDC pressure 128 may be a reading, as measured by a pressure transducer, or the actual EDC pressure 128 can be an estimate. The pressure regulation module 180 closed-loop uses a difference to the EDC 54 to control. The EDC 54 may be present as a separate device in the drive train. In one embodiment, the EDC 54 be part of the transmission and / or be controlled with this. The actual EDC pressure 128 is determined by the clutch pressure torque model 200 used a reaction torque 132 in the EDC 54 appreciate. In addition, the pressure-torque compensation model uses 205 the actual EDC pressure 128 to a torque compensation value 134 for nonlinearity, time delay and temperature effects. reaction torque 132 and the torque compensation value 134 be in summation module 215 adds up to an EDC torque estimate 148 to build. The clutch torque compensation module 210 uses the EDC torque estimate 148 to T _{m_comp} 136 to investigate. The propulsion torque control module 130 monitors the current output speed 104 and the output torque request 102 to the engine torque command 142 and T _{m_propel} 138 to investigate. The summation module 110 adds T _{m_comp} 136 , T _{m_propel} 138 and signal 144 to T _{m_cmd} 146 to the Control the engine or engines of the vehicle to determine. The control module 110 for flying engine start provides an exemplary embodiment of a control module to carry out the disclosed methods, however, it should be understood that a number of different embodiments of control modules may be used and that the disclosure is not intended to be limited to the exemplary embodiment disclosed herein.

Hydraulic pressure to the EDC or other clutches may be a function of controlling a main hydraulic pump, which is often associated with the input speed of the transmission, and an auxiliary pump. The control of the main and auxiliary pumps and the hydraulic pressure delivered to the system that controls the clutches may include controlling discharge pressures from one or the other pump and regulating the pressure on the system accordingly. Clutches include clutch fill events where a clutch is quickly inflated to a point where it is ready to apply pressure to the associated clutch linings or the clutch touch point is filled. Such a point may be referred to as the point of onset torque in the clutch.

According to one embodiment of a flying engine start, the flying engine start can be divided into four stages, stages A to D. Stage A is a machine turning stage in which the engine torque command is zero and torque is applied by one or both electric motors to power up the engine. In one embodiment, an engine torque command to the second engine is increased to compensate for the engine disconnect clutch torque based on an EDC clutch torque estimate. In stage B, the engine has fired and engine torque commands are used to bring the engine speed close to synchronization with the second engine in a control mode. The control of the first motor may be used to assist the engine during stage B, or the first engine may be commanded to idly cycle. Along with engine torque control, the engine disconnect clutch is under slip control to achieve a desired EDC speed difference between engine speed and second engine speed and associated transmission input speed. In stage C, the engine speed is close to the transmission input speed, and the EDC speed difference or EDC slip is reduced to the minimum desired level by clutch slip control, with most of the torque for controlling engine speed being provided by one or both of the engines, with minimum Engine torque is commanded. This is to minimize engine torque torsional disturbances on the driveline when the engine disconnect clutch locks. In stage D, the engine disconnect clutch is disabled, and engine torque is increased while engine torques are reduced, thereby completing the engine start sequence. The control of a powertrain by such a flying engine start is disclosed in co-pending and assignee U.S. Patent Application No. 13 / 216,311, which is incorporated herein by reference.

3 graphically illustrates an exemplary flying engine start including using torque from the engine to achieve a synchronization speed and engine 62 used to engine 20 to assist with the flying machine start. In an upper portion of the figure, a horizontal axis illustrates a time in seconds, and a vertical axis illustrates a shaft speed in revolutions per minute. It is an input speed 302 and a machine speed 304 illustrated. In a central portion of the figure, a horizontal axis corresponds to the same period as illustrated in the upper portion, and a vertical axis illustrates the clutch engagement. It is the transmission output clutch 306 and the EDC 308 illustrated. In a lower portion of the figure, a horizontal axis corresponds to the same period as illustrated in the upper portion, and a vertical axis represents torque. They are output torque 310 , Torque 312 for the second engine 20 , Torque 318 for the first engine 62 and engine torque 314 illustrated. The input speed 302 accelerates at a constant rate of zero. The transmission output clutch 306 is initially set to a fully engaged state and is maintained in this state. output torque 310 is set to a value and is held there. In a period that starts when the input speed 302 starts to accelerate, engine torque 312 set to a value to output torque 310 to create. For a period after the entrance 302 starts to accelerate, the engine speed remains 304 at zero and the EDC 308 stays in a disengaged state. At the time 320 Level A of a flying machine start is initiated. EDC 308 Switches to a slip condition, where engine torque 312 can be used to deliver torque to the machine while the engine speed 304 and the input speed 302 different values remain. At the time 320 starts the engine speed 304 on, to accelerate, and engine torques 312 and 318 increase to deliver torque to the machine while the output torque 310 is maintained. torque 318 is controlled to extra torque from the engine 62 to deliver, helping to accelerate the machine. torque 318 can be controlled based on the calibrated behavior of the powertrain or other inputs. At the time 330 reaches the engine speed 304 a machine ignition speed 316 , and level B of the flying machine start can be initiated. At the time 330 For example, the engine may be fired and made operational providing engine torque and engine speed 304 is accelerated on the basis of a machine speed _{profile selected} to reach N _{e_synch} . EDC 308 can be reduced to a minimum level, engine torque 318 can be reduced to zero and engine torque 312 returns to a level that is the output torque 310 maintains without delivering any torque to the machine. In 9 will be at the time 535 Stage C of the flying machine start initiated. In 11 FIG. 12 illustrates a method in which stage C is omitted from the flying engine start and instead engine torque 314 is used to reach N _{e_synch} over an extended level B. Once N _{e_synch} at the time 340 is reached, level D of the flying machine start is initiated, and the EDC 308 can be fully engaged.

There are modes disclosed where the first engine 62 and the second engine 20 can work together to provide a required torque, for example, a target turn-around torque, which is required to the machine 10 to start. 4 Graphically illustrates two engines that cooperatively provide a desired torque. A horizontal axis illustrates a torque-generating branch from first engine to second engine determined according to the disclosed method, wherein values increasing from left to right illustrate an increased contribution from the second engine and a reduced contribution from the first engine. A vertical axis illustrates torque transmitted by the motors. One skilled in the art will recognize that torque transmitted from the engine to a desired shaft, for example, the crankshaft of the engine, may be different from the torque generated by the device, for example as a result of gear ratio changing means, losses in a machine disconnect clutch or the transmitted torque that includes only a portion of the torque generated by a motor. Expression 402 illustrates torque transmitted from the first engine as a contribution to the desired torque, and term 404 illustrates torque transmitted from the second engine as a contribution to the desired torque. value 406 on the vertical axis illustrates a total setpoint torque required for the motors. For each value of the horizontal axis is the value of the expression 402 and the expression 404 equal to the value 406 , As disclosed, in some embodiments, a motor may be used that can not self-deliver a desired torque. In addition, if the engine already providing some other torque is controlled to remain under a particular torque, for example, as a result of determined efficiency values, or if it is necessary to maintain a torque reserve, a maximum torque transmitted by the engine may be used can be defined. In the embodiment of 4 is a maximum torque that can be transmitted from the first motor by value 408 Are defined. As a result, a corresponding torque generation branch value 410 be defined from the first motor to the second motor, wherein the junction between the first motor and the second motor is limited.

Because of the value 408 the first and second motors can not be commanded in the area to the left of the value 410 to work.

5 FIG. 12 illustrates an example process for controlling first and second drivetrain engines. FIG. Table 1 is provided as a key, with the numbered blocks and the corresponding functions performed as follows. Table 1 BLOCK BLOCK CONTENT 502 begin 504 Monitoring a torque supplied by the second motor 506 Monitoring a speed of the second motor 508 Determining a condition of the second motor based on the torque and the speed 510 Selecting a control mode for the first motor based on the condition of the second motor 512 Controlling the first motor and the second motor based on the control mode

process 500 starts at block 502 , At block 504 a torque supplied by the second motor is monitored. At block 506 a speed of the second motor is monitored. At block 508 a condition of the second motor is determined on the basis of the torque and the rotational speed. At block 510 For example, a control mode for the first motor is selected based on the condition of the second motor. At block 512 For example, the first and second motors are controlled based on the control mode. Modifications to the process 500 For example, alternative or additional parameters may be monitored or determined in support of determining the condition of the second motor. In addition, a machine disconnect clutch and / or the engine may be controlled based on the control mode. A number of example powertrain control processes are contemplated, and the disclosure is not limited to the particular exemplary embodiments set forth herein.

The disclosure has described certain preferred embodiments and modifications thereto. Other modifications and variations may come to mind when reading and understanding the description. Therefore, it is intended that the disclosure not be limited to the particular embodiment (s) disclosed as the best mode contemplated for carrying out this disclosure, but that the disclosure will include all embodiments, which fall within the scope of the appended claims.

Claims (10)

A method of controlling a powertrain including a first electric motor coupled to an engine with a gear ratio changing means and a second motor selectively coupled to the engine through a engine disconnect clutch, the second motor further comprising an input shaft of an engine Gearbox, the method comprising: monitoring a propulsion torque provided by the second motor; a speed of the second motor is monitored; determining a condition of the second motor based on the propulsion torque and the rotational speed of the second motor; a control mode for the first motor is selected on the basis of the condition of the second motor; and the first motor, the second motor and the engine disconnect clutch are controlled on the basis of the control mode. The method of claim 1, wherein selecting the control mode for the first engine comprises enabling a flying engine start with cooperating two engines based on comparing the propulsion torque of the second engine with a maximum torque of the second engine. The method of claim 1, wherein selecting the control mode for the first motor comprises activating a flying engine start with the increased contribution of the first motor based on a desired available output torque. Method according to claim 1, wherein selecting the control mode for the first engine includes enabling a flying engine start with only the first engine based on the second engine operating in a low torque disturbance mode; and further comprising in that the engine disconnect clutch is operated in a disengaged state based on the second engine operating in the low torque disturbance mode. The method of claim 1, wherein selecting the control mode for the first motor comprises enabling the flying engine start with only the first engine based on a speed of the second motor being too low to assist the engine start. The method of claim 1, wherein selecting the control mode for the first motor comprises activating a series hybrid mode based on the second motor operating in a creep mode. The method of claim 1, wherein determining the condition of the second engine comprises determining an efficiency of operating the powertrain in a series hybrid mode; wherein selecting the control mode for the first motor comprises activating a series hybrid mode based on the determined efficiency. The method of claim 1, further comprising: the powertrain is operated in a parallel hybrid mode; and wherein selecting the control mode for the first motor comprises determining a torque generation branch from the first motor to the second motor. The method of claim 1, wherein determining the condition of the second motor comprises determining whether a candidate control mode for the first motor would cause the second motor to operate in a power limited range. A method of controlling a powertrain including a first electric motor connected to an internal combustion engine having a pulley drive device and a second motor connected to the engine through a machine disconnect clutch, the second motor further being connected to an input shaft of the transmission wherein the method comprises: Propulsion torque is supplied to the input shaft with the second motor; a speed of the second motor is monitored; determining a condition of the second motor based on the propulsion torque and the rotational speed of the second motor; and a flying engine start is operated based on the condition of the second engine, which comprises: a cranking torque required for the flying engine startup is monitored; determining a proportion of the cranking torque to be supplied by the first motor based on the condition of the second motor; and the first motor, the second motor and the engine disconnect clutch are controlled on the basis of the determined fraction.

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