JP3937948B2 - Control device and method for hybrid vehicle, and hybrid vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase the overall efficiency of a hybrid vehicle in the hybrid vehicle formed by combining an engine in which a compression state such as an intake air compression ratio can be changed with a motor generator device. <P>SOLUTION: This hybrid vehicle comprises the engine and a compression state variable means capable of changing the compression ratio in a combustion chamber. The device also comprises a selection means for selecting, as an optimum combination, such a combination of operation point parameters that the overall efficiency of a power output system is maximized according to actual operating conditions among a plurality of combinations of a plurality of operation point parameters including a compression ratio pre-set in order to achieve a required drive force requested for the power output system according to the plurality of types of the operating conditions and a control means for controlling a compression state variable means so that the compression ration becomes a compression ratio in the selected optimum combination. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of a control device and method for controlling a hybrid vehicle having a hybrid type power output system that is a combination of an engine and a motor generator device, and further includes a hybrid vehicle equipped with the control device. It belongs to the technical field. In particular, the present invention belongs to a technical field such as a control device for controlling a hybrid vehicle using a variable compression state engine capable of changing a compression state such as a compression ratio as such an engine.
[0002]
[Prior art]
For example, as disclosed in JP-A-9-47094 and JP-A-2000-324615, the hybrid type power output system appropriately drives the motor generator device to drive the engine according to the required operating state. The battery is charged by using a generator (generator) rotated by force or using a dedicated generator included in the motor generator device. Further, the drive shaft is rotated alone or together with the engine by using the motor generator device as a motor (electric motor) that rotates by receiving power supply from the battery or by using a dedicated motor included in the motor generator device. As a result, the engine can be continuously operated with basically high driving efficiency, and fuel efficiency and exhaust purification performance are improved.
[0003]
This type of hybrid power output system is roughly divided into a parallel hybrid system and a serial hybrid system. In the former, the drive shaft is rotated by a part of the output of the engine and rotated by the driving force of the motor generator device. In the latter, the engine output is exclusively used for charging by the motor generator device, and the drive shaft is rotated by the driving force of the motor generator device.
[0004]
As a technique for controlling the power output system of such a hybrid vehicle, for example, Japanese Patent Laid-Open No. 2000-204987 discloses an engine control method for suppressing vibration at engine start by controlling a decompression operation in a hybrid vehicle. Is disclosed. In Japanese Patent Application Laid-Open No. 10-2239 and the like, in a hybrid vehicle, by controlling the timing of the engine intake valve and the exhaust valve, the shock is reduced and the fuel efficiency is improved at the time of engine fuel cut control and deceleration by brake operation. An engine control device for a hybrid vehicle has been proposed.
[0005]
Generally, various existing direct injection type and port injection type engines can be used for hybrid vehicles. At this time, a plurality of parameters that define the operation of the engine or the power output system, such as the engine speed and the engine torque, as traditionally performed for engines mounted on ordinary vehicles other than hybrid vehicles. Combinations (simply referred to herein simply as “parameters”) are selected to optimize or maximize engine efficiency. That is, in addition to fuel efficiency improvement by adopting a hybrid type, fuel efficiency improvement is achieved by incorporating an engine with improved engine efficiency in this way.
[0006]
Even in cases other than traditional engines, such optimization or maximization of engine efficiency has been achieved. For example, Japanese Patent Application Laid-Open Nos. 2000-64866 and 6-241058 disclose variable compression ratio engines in which the compression ratio of the engine is variable. Even in the case of this engine, the compression ratio is appropriately changed according to various operating conditions such as high-speed normal driving, low-speed normal driving, acceleration, deceleration, battery charging, etc. It is possible to optimize or maximize engine efficiency.
[0007]
[Problems to be solved by the invention]
However, when any type of engine having high engine efficiency as a single engine is incorporated into a hybrid vehicle, the following problems occur.
[0008]
That is, regardless of the parallel hybrid system or the serial hybrid system, the engine output is transmitted to the motor generator device, or the engine output is assisted by the output of the motor generator device, for example, including a planetary gear. A relatively complex power transmission mechanism exists in the power output system. For this reason, even if parameter settings that optimize or maximize engine efficiency are performed, the entire power output system or hybrid vehicle including the transmission efficiency of the power output system, the power generation efficiency of the motor generator device, etc. The overall energy efficiency (referred to herein simply as “overall efficiency” where appropriate) is not generally optimized.
[0009]
Moreover, if parameter settings that optimize efficiency other than engine efficiency, such as transmission efficiency in the transmission mechanism of the power output system, are taken, the main engine efficiency declines significantly, improving the overall efficiency of the hybrid vehicle. There is a problem that it is very difficult in terms of technology.
[0010]
The present invention has been made in view of the above problems, and in a hybrid vehicle including a power output system in which a compression state variable type engine such as a variable compression ratio type and a motor generator are combined, can improve overall efficiency. It is an object of the present invention to provide a hybrid vehicle control device and method, and a hybrid vehicle including the control device.
[0011]
[Means for Solving the Problems]
  In order to solve the above problems, a control device for a hybrid vehicle according to the present invention includes (i) an engine, compression state variable means capable of changing a compression state in a combustion chamber of the engine, and at least a part of the output of the engine. A hybrid type power output system including a motor generator device capable of generating electric power and outputting a driving force via a drive shaft, (ii) a vehicle body on which the power output system is mounted, and (iii) the A control device that controls a hybrid vehicle that is attached to a vehicle body and includes wheels that are driven by the driving force that is output via the drive shaft, and a plurality of types of driving states that are assumed in the hybrid vehicle The power output system including the compression state, which is preset to achieve the required driving force required for the power output system according to Selecting means for selecting, as an optimal combination, a combination that maximizes the overall efficiency of the power output system in accordance with an actual driving state among a plurality of combinations of parameters that define the operation of the system; Control means for controlling at least the compression state variable means so as to achieve the compression state in the optimum combination, and the compression state variable means can change the compression ratio in the combustion chamber as the compression state. The power output system further includes a power storage device that can be charged by the motor generator device and can supply power to the motor generator device, and the control means is configured to regenerate the power storage device by the motor generator device. When charging, the compression state variable means is controlled so as to reduce the compression ratio.
[0012]
According to the hybrid vehicle control apparatus of the present invention, the hybrid power output system includes the compression state variable means that can change the compression state of the engine. In order to achieve the required driving force required for the power output system in accordance with a plurality of types of driving states assumed in the hybrid vehicle, a plurality of combinations of a plurality of parameters including a compression state are set in advance. Such a combination of a plurality of parameters can be set for each hybrid vehicle in advance by experiment, experience, simulation, or the like. Such parameters include, for example, the engine speed, engine torque, and the like in addition to the compression state that is the intake compression ratio in the combustion chamber (referred to as simply “compression ratio” in the present specification as appropriate). Thereafter, during the operation of the hybrid vehicle, the selecting means increases the overall efficiency of the power output system according to the actual driving state such as the vehicle speed and the amount of depression of the accelerator, among the plurality of combinations thus set. The one that maximizes the maximum is selected as the optimum combination. In response to this, the control means controls at least the compression state varying means so that the compression state in the selected optimum combination is obtained. For example, by controlling at least one of the volume in the combustion chamber and the intake valve timing in the engine, the compression ratio variable means is controlled so that the compression ratio in the selected optimum combination is obtained. As a result, the present invention is compared with the case where the overall efficiency of the hybrid type power output system or hybrid vehicle including the system transmission efficiency, the power generation efficiency, etc. is lowered by the parameter setting for optimizing the engine efficiency as in the prior art. Accordingly, it is possible to increase the overall efficiency. In a conventional hybrid vehicle, the transmission efficiency usually differs significantly depending on the driving state. Therefore, if the engine efficiency is optimized, the overall efficiency of the hybrid vehicle may be lowered.
[0013]
In particular, by using a compression state variable type engine such as a variable compression ratio engine disclosed in, for example, the above-mentioned Japanese Patent Laid-Open Nos. 2000-64866 and 6-241058, the engine efficiency can be improved. In addition, the engine efficiency can be maintained at a relatively high level when the overall efficiency including system transmission efficiency and power generation efficiency is maximized. In other words, if the engine is not a traditional compression state variable type, and the parameter setting is set so as to increase other overall efficiency factors such as system transmission efficiency and power generation efficiency, the engine efficiency will be significantly reduced. The control device of the present invention is very advantageous because there is no problem that it becomes practically difficult to increase the efficiency or the exhaust gas purification performance is significantly reduced due to a decrease in engine efficiency.
[0014]
  In this specification, the power output system of the parallel or serial hybrid system is configured as described above, and the entire heavy electric machine including one or a plurality of motor generators or one or a plurality of generators and motors is included in the system. The connection wiring and the like are referred to as a “motor generator device”. Further, in this specification, in any type of hybrid type, supplementing the output of the engine with the driving force of the motor generator device is referred to as “assist”, and the driving force and driving of the motor generator device at this time The amounts are referred to as “assist force” and “assist amount”, respectively.
  In addition, in the present invention, in particular, the compression state variable means can change a compression ratio in the combustion chamber as the compression state, and the power output system can be charged by the motor generator device and the motor generator. A power storage device capable of supplying power to the device, wherein the control means includes the motor generator device configured to store the power storage device.For regenerationReduce the compression ratio when chargingTo control the compression state variable means.
  Therefore, according to the present invention,For example, in a variable compression ratio type engine, the compression ratio ε is increased at light loads and the compression ratio ε is decreased at heavy loads, and the engine efficiency is optimized. As a result, the overall efficiency is maximized. Can be greatly increased. And for regeneration,When the motor generator device charges the power storage device, that is, during regeneration, under the control of the control means, for example, by controlling the volume of the combustion chamber in the engine and the intake valve timing, the compression state varying means is Reduce the compression ratio. In particular, in general, during regeneration by the motor generator device, the fuel is cut and the engine is rotated. In this case, the regeneration efficiency in the motor generator device is reduced by the amount of friction torque generated by the pumping operation in the engine. However, in the present invention, when the motor generator is regenerated, by reducing the compression ratio, the friction torque in such an engine can be reduced, and the regeneration efficiency in the motor generator device is improved. As a result, the overall efficiency of the entire power output system or the entire hybrid vehicle is also improved.
In one aspect of the hybrid vehicle control device of the present invention, the plurality of parameters further include an engine speed and an engine torque of the engine, and the control means includes the engine speed and the engine speed in the selected optimal combination. The engine is further controlled to achieve engine torque.
According to this aspect, the selection means can select a combination that maximizes the overall efficiency from among the combinations of parameters including the engine speed Ne and the engine torque Te in addition to the compression ratio ε.
In this aspect, in the energy recirculation mode, the control means is the same with the throttle of the engine fully opened, when the overall efficiency is lowered due to the rotation speed of the motor generator device shifting from positive to negative. The engine and the compression state variable means may be controlled so as to return the rotational speed of the motor generator device from negative to positive by increasing the engine rotational speed while achieving driving force.
If configured in this way, under the control of the control means, in the energy recirculation mode, the overall efficiency is lowered by shifting the rotational speed of the motor generator device from positive to negative, but the engine and the compression state variable means are In order to return the rotational speed of the motor generator device from negative to positive, the engine rotational speed is increased while achieving the same driving force with the throttle fully opened. In this energy recirculation mode, since the engine speed is increased while achieving the same driving force, the control means controls the compression state variable means so as to increase the compression ratio. Typically, for example, control is performed to shift the operating point of the engine to the high rotation / low torque side. Accordingly, the decrease in engine efficiency can be made to exceed the increase in power generation efficiency and electric efficiency, or the increase in power generation efficiency, electric efficiency, and transmission efficiency, so that the overall efficiency can be improved. in this way,While improving the transmission efficiency of the power output system, it is possible to minimize the cost of deterioration of the engine efficiency and improve the energy efficiency of the entire hybrid vehicle, that is, the overall efficiency.
  Alternatively, in order to solve the above problems, another hybrid vehicle control device according to the present invention provides: (i) an engine, compression state variable means capable of changing a compression state in the combustion chamber of the engine, and output of the engine A hybrid type power output system including a motor generator device capable of generating power using at least a part and outputting a driving force via a drive shaft; and (ii) a vehicle main body on which the power output system is mounted; (iii) A control device that controls a hybrid vehicle that is attached to the vehicle body and includes wheels that are driven by the driving force that is output via the drive shaft. Before including the compression state preset to achieve the required driving force required for the power output system according to the type of driving state A selection means for selecting, as an optimal combination, a plurality of combinations of a plurality of parameters that define the operation of the power output system, that selects the one that maximizes the overall efficiency in the power output system according to the actual operating state; Control means for controlling at least the compression state variable means so as to achieve the compression state in the selected optimal combination, and the compression state variable means can change the compression ratio in the combustion chamber as the compression state AndThe plurality of parameters further include an engine speed and an engine torque of the engine, and the control means further controls the engine so as to be the engine speed and the engine torque in the selected optimal combination. In the energy recirculation mode, the control means is configured to maintain the same driving force with the engine throttle fully open when the overall efficiency is reduced due to the rotation speed of the motor generator device shifting from positive to negative. The engine and the compression state variable means are controlled so as to return the rotational speed of the motor generator device from negative to positive by increasing the rotational speed of the engine while achieving.
  According to the control apparatus for another hybrid vehicle according to the present invention configured as described above, in the energy recirculation mode under the control of the control means,Although the overall efficiency is lowered when the rotation speed of the motor generator device is shifted from positive to negative, the engine and the compression state variable means are the same with the throttle fully opened to return the rotation speed of the motor generator device from negative to positive. Increase engine speed while achieving driving force.Therefore, it is possible to improve the energy efficiency of the entire hybrid vehicle, that is, the overall efficiency while minimizing the cost of deterioration of the engine efficiency while improving the transmission efficiency of the power output system.
[0015]
In one aspect of the hybrid vehicle control device of the present invention, the power output system selectively transmits the output of the engine to the drive shaft and the motor generator device, and outputs the output of the motor generator device to the drive shaft. A transmission mechanism having a planetary gear for selectively transmitting to the system, and the overall efficiency is approximated by a product of a system transmission efficiency in the transmission mechanism and an engine efficiency in the engine.
[0016]
According to this aspect, the overall efficiency is approximated by a multiplication value of the system transmission efficiency in the transmission mechanism having the planetary gear and the engine efficiency in the engine, and this approximated overall efficiency is maximized by controlling the compression normal variable means. Thus, the true overall efficiency of the power output system or the hybrid vehicle can be increased.
[0017]
Alternatively, in another aspect of the hybrid vehicle control device of the present invention, the power output system transmits the output of the engine directly to the motor generator device and transmits the output of the motor generator device to the drive shaft. The transmission system further includes a transmission mechanism, and the overall efficiency is approximated by a multiplication value of power generation efficiency in the motor generator device and engine efficiency in the engine.
[0018]
According to this aspect, the output of the engine is transmitted directly to the motor generator device by the transmission mechanism, and the output of the motor generator device is transmitted to the drive shaft. At this time, the output of the motor generator may be transmitted via, for example, a CVT (Continuously Variable Transmission) or a differential gear. In such a configuration, the overall efficiency is approximated by a multiplication value of the power generation efficiency and the engine efficiency in the motor generator device, and the approximated overall efficiency is maximized by the control of the compression normal variable means, whereby the power The true overall efficiency of the output system or hybrid vehicle can be increased.
[0019]
Alternatively, in another aspect of the hybrid vehicle control device of the present invention, the power output system transmits the output of the engine to the motor generator device via a transmission and transmits the output of the motor generator device to the drive shaft. The plurality of parameters further include a gear ratio in the transmission and an assist amount by the motor generator device in addition to the compression state.
[0020]
According to this aspect, the output of the engine is transmitted to the motor generator device by a transmission mechanism, for example, via a transmission such as automatic or manual, and the output of the motor generator device is further transmitted to the drive shaft. At this time, the output of the motor generator may be transmitted through, for example, a differential gear. In such a configuration, a plurality of parameter combinations including a gear ratio in the transmission and an assist amount by the motor generator device are selected as a plurality of parameters according to the actual driving state in addition to the compression state. Select the optimal combination that maximizes the overall efficiency. Thereby, the overall efficiency in the power output system or the hybrid vehicle can be increased.
[0021]
In this aspect, the selection means includes, as the compressed state, (i) an output of the engine to which an assist force by the motor generator device is added that is output via the transmission having the predetermined high gear ratio. One compression state that achieves one required driving force, and (ii) an output of the engine that is output through the transmission having the high gear ratio and to which the assist force by the motor generator device is not added. The combination including the compression state that further increases the overall efficiency may be selected from the other compression states that achieve the one required driving force.
[0022]
With this configuration, there are two compression states such as a compression ratio that achieve the same required driving force depending on whether or not the engine is assisted by the generator device in the hybrid power output system. A combination is selected that includes a compression state that is more efficient. Therefore, the overall efficiency in the power output system or the hybrid vehicle can be improved.
[0027]
In the aspect relating to the engine speed Ne and the engine torque Te, the selection unit further calculates the required driving force from the vehicle speed and the accelerator depression amount in the hybrid vehicle, and the calculated required driving force includes the Calculating the engine efficiency when the compression ratio is changed with respect to the required engine output allocated to the engine, calculating the engine speed and the engine torque when the compression ratio is changed with respect to the required engine output, A system transmission efficiency in the power output system at the compression ratio is calculated, the overall efficiency is approximated by a multiplication value of the calculated engine efficiency and the calculated system transmission efficiency, and the approximated overall efficiency is maximized. Alternatively, the compression ratio may be selected to be increased.
[0028]
With this configuration, the required driving force is calculated from the vehicle speed and the accelerator depression amount. Of the calculated required driving force, the engine efficiency is calculated when the compression ratio ε is changed with respect to the required engine output (required engine torque) Pe. The engine speed Ne and the engine torque Te when the compression ratio ε is changed with respect to the required engine output Pe are calculated. The system transmission efficiency in the power output system at each compression ratio is calculated. Since the overall efficiency is approximated by the product of the calculated engine efficiency and the calculated system transmission efficiency, the overall efficiency in the power output system or the hybrid vehicle can be improved.
[0031]
In another aspect of the hybrid vehicle control device of the present invention, the control means controls the compression state by controlling at least one of a volume in the combustion chamber and an intake valve timing in the engine.
[0032]
According to this aspect, the compression state such as the compression ratio can be controlled relatively easily and accurately. The volume of the combustion chamber in the engine can change the compression state or the compression ratio by shifting the position of the top dead center or the position of the bottom dead center, for example. Further, the compression state or the compression ratio can be changed by delaying or speeding up the intake valve timing with respect to the piston movement.
[0033]
Here, for example, as disclosed in Japanese Patent Application Laid-Open No. 2000-64866, the supply of hydraulic pressure for increasing the friction between the connecting rod of the engine and the eccentric bearing is used as an eccentric bearing accompanying rotation with the crankshaft. You may change a compression ratio by controlling by the change of a relative rotational position with a crankpin. Alternatively, as disclosed in JP-A-6-241058, the compression ratio may be changed by separately providing a control valve in such a hydraulic pressure supply path and controlling the hydraulic pressure supply.
[0034]
The “motor generator device” in the hybrid power output system according to the present invention includes a plurality of motor generators, and at least one of the plurality of motor generators uses at least a part of the engine output. The power storage device may be charged by generating power, and at least one of the plurality of motor generators may be of a type that outputs power by being supplied with power from the power storage device. For example, the engine is configured to be able to output a driving force to the drive shaft while receiving assistance from a motor generator device. Alternatively, the engine is configured to charge the motor generator device exclusively. In other words, the hybrid vehicle control device of the present invention functions effectively regardless of whether it is a parallel hybrid system or a serial hybrid system. Examples of the “power storage device” according to the present invention include a battery and a large-capacity capacitor.
[0035]
In order to solve the above problems, a hybrid vehicle of the present invention includes the above-described hybrid vehicle control device of the present invention (including various aspects thereof), the power output system, the vehicle body, and the wheels.
[0036]
According to the hybrid vehicle of the present invention, since the hybrid vehicle control device of the present invention described above is provided, the overall efficiency is high, the fuel consumption performance is excellent, and the exhaust gas purification performance is also excellent.
[0037]
  In order to solve the above problems, the hybrid vehicle control method of the present invention includes (i) an engine, compression state variable means capable of changing a compression state in a combustion chamber of the engine, and at least a part of the output of the engine. A hybrid type power output system including a motor generator device capable of generating electric power and outputting a driving force via a drive shaft, (ii) a vehicle body on which the power output system is mounted, and (iii) the A control method for controlling a hybrid vehicle that is attached to a vehicle main body and includes wheels that are driven by the driving force that is output via the drive shaft, and a plurality of types of driving states that are assumed in the hybrid vehicle The power output system including the compression state, which is preset to achieve the required driving force required for the power output system according to A selection step of selecting, as an optimal combination, a combination that maximizes the overall efficiency of the power output system in accordance with an actual operating state among a plurality of combinations of parameters that define the operation of the system; A control step for controlling at least the compression state variable means so as to achieve the compression state in the optimal combination, and the compression state variable means can change a compression ratio in the combustion chamber as the compression state. The power output system further includes a power storage device that can be charged by the motor generator device and can supply power to the motor generator device, and the control step includes the step of regenerating the power storage device by the motor generator device. When charging, the compression state variable means is controlled so as to reduce the compression ratio.
[0038]
According to the hybrid vehicle control method of the present invention, the overall efficiency of the hybrid vehicle can be increased as in the case of the hybrid vehicle control apparatus of the present invention described above.
[0039]
Such an operation and other advantages of the present invention will become apparent from the embodiments described below.
[0040]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the hybrid vehicle control device according to the present invention is applied to a parallel hybrid hybrid vehicle, and the hybrid vehicle control method according to the present invention is executed in the hybrid vehicle. Is.
[0041]
(Basic configuration and operation of hybrid vehicle)
First, the structure of the hybrid vehicle of this embodiment is demonstrated using FIG. FIG. 1 is a block diagram of a power system in the hybrid vehicle of this embodiment.
[0042]
In FIG. 1, the power system of the hybrid vehicle of the present embodiment includes an engine 150, motor generators MG1 and MG2 constituting an example of a motor generator device, drive circuits 191 and 192 for driving these motor generators MG1 and MG2, respectively. And a control unit 190 for controlling the drive circuits 191 and 192, and an EFIECU (Electrical Fuel Injection Engine Control Unit) 170 for controlling the engine 150.
[0043]
Particularly in the present embodiment, the engine 150 is a variable compression ratio gasoline engine configured to be able to change the compression ratio in the combustion chamber. The operation for changing the compression ratio will be described in detail later.
[0044]
Engine 150 rotates crankshaft 156. The operation of engine 150 is controlled by EFIECU 170. The EFIECU 170 is a one-chip microcomputer having a CPU, ROM, RAM, etc. therein, and the CPU executes control of the fuel injection amount, the rotational speed, and the like of the engine 150 in accordance with a program recorded in the ROM. Although not shown, various sensors that indicate the operation state of the engine 150 are connected to the EFIECU 170 in order to enable these controls.
[0045]
Motor generators MG1 and MG2 are configured as synchronous motor generators, and include rotors 132 and 142 having a plurality of permanent magnets on the outer peripheral surface, and stators 133 and 143 wound with a three-phase coil that forms a rotating magnetic field. Prepare. The stators 133 and 143 are fixed to the case 119. Three-phase coils wound around stators 133 and 143 of motor generators MG1 and MG2 are connected to battery 194 via drive circuits 191 and 192, respectively.
[0046]
The drive circuits 191 and 192 are transistor inverters each including two transistors as switching elements for each phase. The drive circuits 191 and 192 are connected to the control unit 190, respectively. When the transistors of drive circuits 191 and 192 are switched by a control signal from control unit 190, a current flows between battery 194 and motor generators MG1 and MG2.
[0047]
Each of motor generators MG1 and MG2 can also operate as a motor (electric motor) that rotates by receiving power supplied from battery 194 (hereinafter, this operating state is referred to as “powering” as appropriate). Alternatively, when the rotors 132 and 142 are rotated by an external force, the battery 194 can be charged by functioning as a generator (generator) that generates electromotive force at both ends of the three-phase coil (hereinafter, this operation is appropriately performed). The state is called “regeneration”).
[0048]
Engine 150 and motor generators MG1 and MG2 are mechanically coupled via planetary gear 120, respectively. Planetary gear 120 is also called a planetary gear, and has three rotating shafts coupled to the gears shown below. The gears constituting the planetary gear 120 are a sun gear 121 that rotates at the center, a planetary pinion gear 123 that revolves while rotating around the periphery of the sun gear, and a ring gear 122 that rotates at the outer periphery thereof. The planetary pinion gear 123 is pivotally supported by the planetary carrier 124. In the hybrid vehicle of this embodiment, the crankshaft 156 of the engine 150 is coupled to the planetary carrier shaft 127 via the damper 130. The damper 130 is provided to absorb torsional vibration generated in the crankshaft 156. Rotor 132 of motor generator MG1 is coupled to sun gear shaft 125. Rotor 142 of motor generator MG2 is coupled to ring gear shaft 126. The rotation of the ring gear 122 is transmitted to the drive shaft 112 and further to the wheels 116R and 116L via the chain belt 129.
[0049]
Next, the operation in the power system of the hybrid vehicle of the present embodiment configured as described above will be described.
[0050]
First, the operation of the planetary gear 120 will be described with reference to FIGS.
[0051]
In the planetary gear 120, when the rotation speed and torque of the two rotation shafts among the three rotation shafts described above are determined (hereinafter appropriately referred to as “rotation state”), the rotation state of the remaining rotation shafts is determined. It has the property of being determined. The relationship between the rotational states of the respective rotating shafts can be obtained by a calculation formula well known in mechanics, but can also be obtained geometrically by a diagram called a collinear diagram.
[0052]
FIG. 2 shows an example of an alignment chart. The vertical axis indicates the number of rotations of each rotation axis. The horizontal axis shows the gear ratio of each gear in a distance relationship. The sun gear shaft 125 (S in the figure) and the ring gear shaft 126 (R in the figure) are taken at both ends, and the position C that internally divides the position S and the position R into 1: ρ is the position of the planetary carrier shaft 127. ρ is the ratio of the number of teeth of the sun gear 121 to the number of teeth of the ring gear 122. The rotation speeds Ns, Nc and Nr of the rotation shafts of the respective gears are plotted at the positions S, C and R thus defined. The planetary gear 120 has the property that the three points plotted in this way are always aligned. This straight line is called an operation collinear line. The movement collinear line is uniquely determined if two points are determined. Therefore, by using the operation collinear line, the rotation speed of the remaining rotation shafts can be obtained from the rotation speeds of the two rotation shafts among the three rotation shafts.
[0053]
The planetary gear 120 has the property that when the torque of each rotating shaft is replaced with a force acting on the operating collinear line, the operating collinear line is maintained as a rigid body. As a specific example, a torque acting on the planetary carrier shaft 127 is assumed to be Te. At this time, as shown in FIG. 2, a force having a magnitude corresponding to the torque Te is applied to the operation collinear line from the vertical bottom to the top at the position C. The direction to be applied is determined according to the direction of the torque Te. Further, the torque Tr output from the ring gear shaft 126 is caused to act on the operation collinear line at the position R from vertically above to below. Tes and Ter in the figure are obtained by distributing the torque Te into two equivalent forces based on the distribution law of the force acting on the rigid body. There is a relationship of “Tes = ρ / (1 + ρ) × Te” and “Ter = 1 / (1 + ρ) × Te”. In consideration of the condition that the operation nomogram is balanced as a rigid body in the state where the above forces are applied, a torque Tm1 to be applied to the sun gear shaft 125 and a torque Tm2 to be applied to the ring gear shaft are obtained. be able to. The torque Tm1 is equal to the torque Tes, and the torque Tm2 is equal to the difference between the torque Tr and the torque Ter.
[0054]
When the engine 150 coupled to the planetary carrier shaft 127 is rotating, the sun gear 121 and the ring gear 122 can rotate in various rotational conditions under the conditions that satisfy the above-described conditions regarding the operation collinearity. When the sun gear 121 is rotating, electric power can be generated by the motor generator MG1 using the rotational power. When the ring gear 122 is rotating, the power output from the engine 150 can be transmitted to the drive shaft 112. In the hybrid vehicle having the configuration shown in FIG. 1, the power output from the engine 150 is distributed to the power mechanically transmitted to the drive shaft and the power regenerated as electric power, and the regenerated electric power is used. By driving the motor generator MG2 to assist the power, the vehicle can travel while outputting desired power. Such an operating state is a state that can be taken during normal traveling of the hybrid vehicle. When the load is high, such as during full-open acceleration, electric power is also supplied from the battery 194 to the motor generator MG2 to increase the power transmitted to the drive shaft 112.
[0055]
In the hybrid vehicle described above, since the power of motor generator MG1 or MG2 can be output from drive shaft 112, it is possible to travel using only the power output by these motors. Therefore, even when the vehicle is traveling, the engine 150 may be stopped or may be in a so-called idle operation. This operation state is a state that can be taken when starting or running at a low speed.
[0056]
Furthermore, in the hybrid vehicle of the present embodiment, the power output from the engine 150 can be transmitted only to the drive shaft 112 side instead of being distributed to the two paths. This is an operational state that can be taken during high-speed steady traveling, where the motor generator MG2 is driven by inertia due to high-speed traveling, and travels only with the power output from the engine 150 without assistance from the motor generator MG2.
[0057]
FIG. 3 shows a nomographic chart at the time of this high-speed steady running. In the alignment chart shown in FIG. 2, the rotational speed Ns of the sun gear shaft 125 is positive. However, the rotational speed Ns of the engine 150 and the rotational speed Nr of the ring gear shaft 126 are negative as shown in FIG. It becomes. At this time, in motor generator MG1, the direction of rotation and the direction in which torque acts are the same, so motor generator MG1 operates as an electric motor and consumes electrical energy represented by the product of torque Tm1 and rotation speed Ns. (Reverse power running state). On the other hand, in motor generator MG2, the direction of rotation and the direction in which torque acts are reversed, so that motor generator MG2 operates as a generator, and the electric energy represented by the product of torque Tm2 and rotation speed Nr is transferred to the ring gear shaft. It will regenerate from 126.
[0058]
Thus, the hybrid vehicle of this embodiment can travel in various driving states based on the action of the planetary gear 120.
[0059]
Subsequently, the control operation by the control unit 190 will be described with reference to FIG. 1 again.
[0060]
In FIG. 1, the entire operation of the power output system of the present embodiment is controlled by a control unit 190. The control unit 190 is a one-chip microcomputer having a CPU, a ROM, a RAM, and the like in the same manner as the EFIECU 170. The control unit 190 is connected to the EFIECU 170, and both can transmit various information. The control unit 190 is configured to be able to indirectly control the operation of the engine 150 by transmitting information such as a torque command value and a rotation speed command value necessary for controlling the engine 150 to the EFIECU 170. The control unit 190 thus controls the operation of the entire power output system. In order to realize such control, the control unit 190 is provided with various sensors, for example, a sensor 144 for knowing the rotation speed of the drive shaft 112. Since ring gear shaft 126 and drive shaft 112 are mechanically coupled, in this embodiment, sensor 144 for determining the rotational speed of drive shaft 112 is provided on ring gear shaft 126 to control the rotation of motor generator MG2. It is common with the sensor for.
[0061]
(Electric circuit in power system of hybrid vehicle)
Next, with reference to FIG. 4, the electric circuit provided in the power system of the hybrid vehicle of this embodiment will be described in more detail. That is, here, details of the control unit 190, the motor generators MG1 and MG2, the drive circuits 191 and 192, and the battery 194 shown in FIG. 1 will be described.
[0062]
As shown in FIG. 4, inverter capacitor 196, drive circuit 191 connected to motor generator MG1, and drive circuit 192 connected to motor generator MG2 are connected in parallel to battery 194, respectively.
[0063]
Specifically, the battery 194 includes a battery module unit 194a, an SMR (system main relay) 194b, a voltage detection circuit 194c, a current sensor 194d, and the like. The SMR 194b connects / disconnects the power source of the high voltage circuit according to a command from the control unit 190, and is composed of two relays R1 and R2 arranged at the + and-both poles of the battery module unit 194a. The battery 194 is provided with two relays R1 and R2. When the power is connected, the relay R2 is first turned on, then the relay R1 is turned on. When the power is shut off, the relay R1 is first turned off, This is because a reliable operation can be performed by turning off the relay R2. The voltage detection circuit 194c detects the total voltage value of the battery module unit 194a. The current sensor 194d detects an output current value from the battery module unit 194a. Output signals of the voltage detection circuit 194c and the current sensor 194d are transmitted to the control unit 190.
[0064]
Drive circuits 191 and 192 are power converters that convert a high-voltage direct current of the battery and an alternating current for motor generators MG1 and MG2, and more specifically, a three-phase bridge circuit composed of six power transistors 191a and 192a are provided, respectively, and DC current and three-phase AC current are converted by the three-phase bridge circuits 191a and 192a.
[0065]
The drive circuits 191 and 192 are provided with voltage detection circuits 191b and 192b, respectively. Voltage detection circuits 191b and 192b detect back electromotive voltages of motor generators MG1 and MG2, respectively. The driving of the power transistors of the three-phase bridge circuits 191a and 192a is controlled by the control unit 190, and the voltage values detected by the voltage detection circuits 191b and 192b from the driving circuits 191 and 192 to the control unit 190 Information necessary for current control such as a current value detected by a current sensor (not shown) provided between the three-phase bridge circuits 191a and 192a and the motor generators MG1 and MG2 is transmitted.
[0066]
(Direct injection gasoline engine)
Next, with reference to FIG. 5, the direct injection engine provided in the hybrid vehicle of the present embodiment will be described in more detail. That is, the details of the engine 150 shown in FIG. 1 will be described here.
[0067]
As shown in FIG. 5, the engine 150 is a so-called direct injection gasoline engine that directly injects fuel into the fuel chamber. Engine 150 is controlled by EFIECU 170. The engine 150 includes a cylinder block 514. A cylinder 516 is formed inside the cylinder block 514. Although engine 150 includes a plurality of cylinders, for convenience of explanation, FIG. 5 shows one cylinder 516 among the plurality of cylinders.
[0068]
A piston 518 is disposed inside the cylinder 516. The piston 518 can slide in the vertical direction in FIG. 5 inside the cylinder 516. A combustion chamber 520 is formed above the piston 518 inside the cylinder 516. In the combustion chamber 520, the injection port of the fuel injection valve 522 is exposed. During operation of the engine 150, fuel is pumped from the fuel pump 524 to the fuel injection valve 522. The fuel injection valve 522 and the fuel pump 524 are connected to the EFIECU 170. The fuel pump 524 pumps fuel to the fuel injection valve 522 side according to a control signal supplied from the EFIECU 170. Further, the fuel injection valve 522 injects fuel into the combustion chamber 520 in accordance with a control signal supplied from the EFIECU 170.
[0069]
Further, the tip of the spark plug 526 is exposed in the combustion chamber 520. The spark plug 526 ignites the fuel in the combustion chamber 520 when supplied with an ignition signal from the EFIECU 170. An exhaust pipe 530 communicates with the combustion chamber 520 through an exhaust valve 528. Each branch pipe of an intake manifold 534 communicates with the combustion chamber 520 via an intake valve 532. The intake manifold 534 communicates with the surge tank 536 on the upstream side. An intake pipe 538 communicates with the surge tank 536 further upstream.
[0070]
A throttle valve 540 is disposed in the intake pipe 538. The throttle valve 540 is connected to the throttle motor 542. The throttle motor 542 is connected to the EFIECU 170. Throttle motor 542 changes the opening of throttle valve 540 in accordance with a control signal supplied from EFIECU 170. A throttle opening sensor 544 is disposed in the vicinity of the throttle valve 540. The throttle opening sensor 544 outputs an electric signal corresponding to the opening of the throttle valve 540 (hereinafter referred to as the throttle opening SC as appropriate) to the EFIECU 170. The EFIECU 170 detects the throttle opening SC based on the output signal of the throttle opening sensor 544.
[0071]
The EFIECU 170 is also connected with an ignition switch 576 (hereinafter referred to as an IG switch 576). EFIECU 170 detects the on / off state of IG switch 576 based on the output signal of IG switch 576. When the IG switch 576 is switched from the on state to the off state, fuel injection by the fuel injection valve 522, fuel ignition by the spark plug 526, and fuel pressure feeding by the fuel pump 524 are stopped, and the operation of the engine 150 is stopped. The
[0072]
An accelerator opening sensor 580 is disposed in the vicinity of the accelerator pedal 578. The accelerator opening sensor 580 outputs an electric signal corresponding to the amount of depression of the accelerator pedal 578 (hereinafter referred to as accelerator opening AC as appropriate) to the EFIECU 170. The EFIECU 170 detects the accelerator opening AC based on the output signal of the accelerator opening sensor.
[0073]
In the present embodiment, the intake pipe 538 is provided with a turbocharger 539. For example, the compressed air is turbocharged into the intake pipe 538 by a turbine linked to the turbine provided on the exhaust pipe 530 side. It is configured as follows. Further, the rotational axis of turbocharger 539 is driven by a dedicated motor generator different from motor generators MG1 and MG2, and the supercharging pressure due to turbocharging is increased by increasing the rotational speed. That is, “turbo assist” is configured to be executable. The dedicated motor generator is configured such that the exhaust energy of the engine 150 on the exhaust pipe 530 side can be regenerated by power generation. Further, the turbocharger 539 may be configured to variably increase the in-cylinder pressure at a specific timing under the control of the EFIECU 170.
[0074]
In the present embodiment, the exhaust pipe 530 is provided with a three-way catalyst device 531, thereby improving the exhaust gas purification performance. In addition, the purification performance of the three-way catalyst device 531 is significantly reduced unless the temperature is higher than a certain temperature. Therefore, a temperature sensor 531T is attached to the three-way catalyst device 531, and the catalyst temperature TCA is detected and input to the EFIECU 170 as catalyst temperature information. Alternatively, such catalyst temperature TCA may be estimated indirectly based on other detection information such as the engine speed in engine 150. The catalyst temperature TCA detected or estimated in this way is used for engine control so that the catalyst temperature TCA does not drop below a certain temperature.
[0075]
The engine 150 according to the present embodiment described above includes a “variable compression ratio device” described below, and is configured to be able to change the compression ratio in the combustion chamber 520 under the control of the EFIECU 170 or the like.
[0076]
(Variable compression ratio device for changing the compression ratio)
Next, a variable compression ratio device configured to be able to change the compression ratio in the combustion chamber of the engine as an example of the compression state varying means according to the present invention will be described with reference to FIGS. Here, for example, a variable compression ratio device provided in the engine in order to cause the above-described direct injection gasoline engine to function as a variable compression ratio engine will be described. Further details of such a variable compression ratio apparatus are described in Japanese Patent Application Laid-Open No. 2000-64866.
[0077]
6 is a partial cross-sectional side view of an embodiment of a variable compression ratio device that can be used in the present embodiment, FIG. 7 is an enlarged view of a part of FIG. 6, and FIGS. It is the axial direction fragmentary sectional view which showed the relative rotational positional relationship with an eccentric bearing with time.
[0078]
6 to 14, the variable compression ratio device includes a large end 2 of the connecting rod 1, a crankshaft 11, a crankpin 12, a crank arm 13, and a crank journal 14. The variable compression ratio device includes an eccentric bearing 21 inserted between the large end 2 of the connecting rod and the crank pin 12 in order to change the compression ratio of the internal combustion engine, a flange 22 provided on the eccentric bearing 21, and an eccentric bearing. The lock pin engagement hole 23 formed in the inner periphery of 21 is provided. The variable compression device includes a lubrication hydraulic supply passage 24 that can communicate with the crankshaft hydraulic supply passage 31 to lubricate between the eccentric bearing 21 and the large end 2 of the connecting rod, an oil pump (not shown), and a crank. The crankshaft hydraulic pressure supply passage 31 extending to the outer periphery of the pin 12, the circumferential groove-shaped hydraulic pressure supply passage 32 extending in the circumferential direction formed on the inner periphery of the eccentric bearing 21, and the inner periphery of the eccentric bearing 21. An axial hydraulic pressure supply path 33 extending in the axial direction from the circumferential groove-shaped hydraulic pressure supply path 32 is formed. The variable compression ratio device further includes a lock pin 41 that can be engaged with the lock pin engagement hole 23 to fix the crank pin 12 and the eccentric bearing 21, and the lock pin 41 to lock the compression pin at a high compression. Lock pin spring 42 for biasing toward the engagement hole 23 side, high compression engagement end 43 that engages in the lock pin engagement hole 23 when the compression ratio is high compression, and compression ratio is low compression Is provided with a low compression engagement end 44 that engages in the lock pin engagement hole 23. Further, a lock pin hydraulic pressure supply passage 45 for supplying hydraulic pressure is provided to urge the lock pin 41 toward the lock pin engagement hole 23 in order to fix the compression ratio to a low compression.
[0079]
As shown in FIG. 8, when the compression ratio is fixed at high compression, the lock pin 41 is not supplied with hydraulic pressure via the lock pin hydraulic pressure supply passage 45, and therefore, the lock pin engagement hole 23, the high compression engagement end of the lock pin 41 is engaged, and the crank pin 12 and the eccentric bearing 21 are fixed so that the relative rotational position does not change. Further, the crankshaft hydraulic pressure supply passage 31 communicates between the connecting rod 1 and the eccentric bearing 21 via the lubricating hydraulic pressure supply passage 24, and the connecting rod 1 and the eccentric bearing 21 are lubricated. During rotation of the crankshaft, the crankpin 12 and the eccentric bearing 21 do not slide, but the eccentric bearing 21 and the connecting rod 1 slide.
[0080]
When the compression ratio is changed from high compression to low compression, first, as shown in FIG. 9, hydraulic pressure is supplied to the lock pin 41 via the lock pin hydraulic supply passage 45, and the crank pin 12, the eccentric bearing 21, Is released. Therefore, not only the eccentric bearing 21 and the connecting rod 1 but also the crank pin 12 and the eccentric bearing 21 can slide with the rotation of the crankshaft.
[0081]
As shown in FIG. 10, when the crankshaft rotates, the crankpin 12 and the eccentric bearing 21 slide, and the relative rotational position of the crankpin 12 and the eccentric bearing 21 changes. As a result, the crankshaft hydraulic pressure supply path 31 is not in communication with the lubricating hydraulic pressure supply path 24, and instead is in communication with the circumferential groove-shaped hydraulic pressure supply path 32. As shown in detail in FIG. 7, the circumferential groove-shaped hydraulic pressure supply passage 32 communicates with the right end (FIG. 7) end surface of the flange 22 through the axial hydraulic pressure supply passage 33. Therefore, the hydraulic pressure supplied via the hydraulic pressure supply paths 31, 32, and 33 presses the eccentric bearing 21 to the left side (FIG. 7), that is, the flange 22 against the axial end surface of the connecting rod 1. As a result, the friction between the connecting rod 1 and the eccentric bearing 21 is increased. On the other hand, the circumferential groove-like hydraulic pressure supply passage 32 extends in the circumferential direction and is formed between the crankpin 12 and the eccentric bearing 21, so that the gap between the crankpin 12 and the eccentric bearing 21 is lubricated. Therefore, as shown in FIGS. 11 and 12, the crankpin 12 rotates with respect to the eccentric bearing 21 while a large friction is generated between the connecting rod 1 and the eccentric bearing 21 during the rotation of the crankshaft. To do.
[0082]
When the relative rotational position of the eccentric bearing 21 and the crank pin 12 is in the state shown in FIG. 12, as described above, the hydraulic pressure is supplied to the lock pin 41 via the lock pin hydraulic supply passage 45. As shown in FIG. 13, the low compression engagement end 44 of the lock pin 41 engages with the lock pin engagement hole 23. As a result, the crankpin 12 and the eccentric bearing 21 are fixed so that the relative rotational position does not change, and the compression ratio is fixed to low compression. Similarly to the state shown in FIG. 8, the crankshaft hydraulic pressure supply path 31 communicates between the connecting rod 1 and the eccentric bearing 21 via the lubricating hydraulic pressure supply path 24. 21 is lubricated. As shown in FIGS. 13 and 14, when the compression ratio is fixed, the crankpin 12 and the eccentric bearing 21 do not slide while the crankshaft rotates, and the eccentric bearing 21 and the connecting rod 1 slide. .
[0083]
As described above, according to the present embodiment, the hydraulic pressure supply passages 31, 32, and 33 that supply hydraulic pressure to increase the friction between the connecting rod 1 and the eccentric bearing 21 are provided with the eccentric bearing 21 accompanying the rotation of the crankshaft. And the crank pin 12 are controlled to communicate with each other by changing the relative rotational position. For this reason, according to this embodiment, it does not have a special control valve for the communication control concerned.
[0084]
However, for example, as disclosed in Japanese Patent Application Laid-Open No. 6-241058, a variable compression apparatus having such a control valve for communication control is used to change the compression ratio variable type according to the present embodiment described below. It is also possible to build an engine.
[0085]
(Compression ratio optimization method in the engine)
Next, a method for optimizing the compression ratio in the variable compression ratio engine provided in the parallel hybrid hybrid vehicle described above will be described with reference to FIGS. FIG. 15 is a characteristic diagram schematically showing how the engine WOT (wide open throttle: full load) line changes when the compression ratio is changed. FIG. 16 is a flowchart showing the optimization method, and FIG. 17 is a conceptual diagram schematically showing how various efficiencies change with respect to changes in the compression ratio in the main process.
[0086]
First, as shown in FIG. 15, the engine WOT line shown on the characteristic diagram (hereinafter, simply referred to as “characteristic diagram” where appropriate) is shown with the engine speed Ne on the horizontal axis and the engine torque Te on the vertical axis. The engine torque Te that can be obtained at the same engine speed Ne increases as the compression ratio ε (that is, the intake compression ratio in the combustion chamber of the engine) becomes smaller as indicated by the arrow “↑ εsmall”. That is, for the same engine, a larger engine torque Te can be obtained by reducing the compression ratio ε.
[0087]
In general, during normal driving of a hybrid vehicle, the engine efficiency can be improved by setting the combination condition of the engine speed Ne and engine torque Te or the “operating point (operating point)” on the characteristic diagram on such a WOT line. . If the compression ratio ε is reduced, the engine fuel consumption hardly changes within an appropriate range on the characteristic diagram. However, in the power output system of the parallel hybrid system, if the compression ratio ε is increased on the engine WOT line, knocking is likely to occur. Therefore, in order to improve fuel economy, the air amount is reduced to some extent using the intake valve timing. It is desirable to narrow down. At this time, if the air amount is reduced, the engine torque Te decreases, so it is good to select not only the operating point at “full load” but also the operating point at a light load under operating conditions with a low engine speed Ne. become.
[0088]
In particular, according to the research by the inventors of the present application, in the hybrid vehicle of the parallel hybrid system, especially in the energy recirculation mode in which the vehicle travels constantly at a high vehicle speed, the operating point with high engine efficiency as described above on the characteristic diagram is assumed. Even if selected, the overall efficiency (system efficiency) of the entire power output system including the power generation efficiency and electric efficiency of the motor generator device, the transmission efficiency of the driving force transmission mechanism including the planetary gear, etc. or the entire hybrid vehicle (system efficiency) Has been confirmed to get worse. In addition, since the required engine torque is generally small in steady running, selecting an operating point that increases the engine efficiency may greatly deviate from increasing the overall efficiency.
[0089]
Incidentally, in the case of a vehicle having a traditional manual or automatic transmission, the transmission efficiency at which the engine torque is transmitted to the axle via the transmission gear is hardly changed depending on the driving state such as the vehicle speed.
[0090]
On the other hand, in a hybrid vehicle, in particular, a parallel hybrid system equipped with a planetary gear, the transmission efficiency varies greatly depending on changes in driving conditions such as vehicle speed and accelerator depression. More specifically, in the case of the hybrid type power output system using the planetary gear described above, the motor generator enters the “power running” state in accordance with the change in the engine speed Ne corresponding to the change in the operation state. Or “regeneration”. For this reason, for example, although power generation is possible in the same operating state, energy is consumed by the motor generator to transmit the engine torque Te to the axle, or excessive and unnecessary driving force is regenerated. The suppression operation and the assist operation are performed in the same manner between the two motor generators (for example, MG1 and MG2) depending on the situation of the change in the rotational speed of the motor generator, and the transmission efficiency changes greatly.
[0091]
Here, according to the theory of the present embodiment, for example, when the overall efficiency is remarkably lowered when the rotational speed of the motor generator (MG1 or the like) shifts from positive to negative, the engine rotational speed is achieved while achieving the same driving force. By increasing Ne, that is, by returning the rotational speed of the motor generator (MG1 or the like) from negative to positive while lowering the engine efficiency to some extent, the decrease in engine efficiency is reduced by the increase in power generation efficiency or system transmission efficiency. To exceed. As a result, overall efficiency can be increased.
[0092]
On the other hand, according to the study of the present inventor, increasing the overall efficiency while lowering the engine efficiency in a general engine in this way is an operating point that deviates significantly from the operating point where the engine efficiency is high on the characteristic diagram. It is technically difficult to operate because of a significant decrease in engine efficiency.
[0093]
As a result of these considerations, in the present embodiment, the above-described variable compression ratio engine is used. In addition, as a parameter defining the operating point (hereinafter simply referred to as “operating point parameter” as appropriate), the “compression ratio ε” is changed to the basic operating point parameters “engine speed Ne” and “engine torque Te”. In addition, as the combination of the plurality of operating point parameters, the optimum one for increasing the overall efficiency is selected. Further, control is performed so as to perform actual engine operation and motor generator operation in accordance with these selected operating point parameters.
[0094]
In FIG. 16, first, “engine compression ratio optimization logic” for optimizing the engine compression ratio is started repeatedly or irregularly, for example, by interrupt processing (step S10). Then, based on the vehicle speed detected by the vehicle speed sensor and the accelerator opening degree AC, the required engine power required in the drive shaft (or ring gear shaft) for traveling the vehicle with respect to the engine 150 and the motor generators MG1 and MG2. Pe is calculated (step S11).
[0095]
Subsequently, the engine efficiency when the compression ratio ε is changed with respect to the same required engine power Pe is calculated (step S12).
[0096]
Here, for example, the map showing the engine efficiency defined by the required engine power Pe and the compression ratio ε created on the assumption that WOT (full load) is provided as a map unique to the hybrid vehicle shown on the left side of the upper stage of FIG. Calculated from 901. Thus, for example, as shown in a graph 902 shown on the right side of the upper stage of FIG. 17, the engine efficiency that is a function of the compression ratio ε is calculated. Such a map 901 can be easily created by mapping the fuel efficiency or the fuel efficiency change when the compression ratio is changed based on the WOT premise for the required engine power Pe in advance for each engine. Once the map 901 is created, this is effective as long as the engines are of the same type. Thereafter, when the required engine power Pe is determined during the operation of the actual hybrid vehicle, the horizontal axis indicates the compression ratio ε by referring to the map 901 that is created in advance and held in the internal memory of the EFIECU 170, for example. Thus, a graph 902 with the vertical axis representing engine efficiency can be created relatively quickly and easily.
[0097]
Returning to FIG. 16, the engine speed Ne and the engine torque Te when the compression ratio is changed are calculated from the required engine power Pe (step S13). In parallel with or in parallel with this, the HV system efficiency is calculated by combining the transmission efficiency excluding the engine efficiency in the power output system, the power generation efficiency, the electric efficiency, etc. at each compression ratio ε (step S13). Here, the engine speed Ne and the engine torque Te are determined when the compression ratio ε is changed with respect to the same required accelerator power Pe for various driving conditions such as various vehicle speeds and accelerator depression amounts. It can be calculated by mapping in advance the engine speed Ne and which engine torque Pe, and referring to this. Such a pre-created map may be stored in the built-in memory of the EFIECU 170, for example. On the other hand, the HV system efficiency here is calculated from an efficiency map of a transmission mechanism including a motor generator device, a battery, and a planetary gear, for example. Such an efficiency map may be created in advance as a map unique to the hybrid vehicle and stored in the internal memory of the EFIECU 170, for example. As a result, a graph 903 in which the horizontal axis is the compression ratio ε and the vertical axis is the HV engine efficiency as shown in the middle stage of FIG. 17 can be created relatively quickly and easily.
[0098]
Returning to FIG. 16 again, subsequently, the engine efficiency (graph 902 in the upper part of FIG. 17) as a function of the compression ratio ε calculated in step S12 and the HV system efficiency (function of the compression ratio ε calculated in step S13) ( The graph 903) in the middle of FIG. More specifically, here, a multiplication value (multiplication result) of the engine efficiency and the system efficiency at each compression ratio ε is calculated, and this is adopted as an approximate value of the overall efficiency. As a result, for example, as shown in a graph 904 shown in the lower part of FIG. 17, the overall efficiency that is a function of the compression ratio ε is calculated.
[0099]
The engine efficiency shown in the graph 902 is an efficiency indicating how much power is generated on the engine / crankshaft or how much energy can be obtained with respect to fuel injection / amount of fuel. On the other hand, the HV system efficiency is an efficiency indicating how much power generated on the crankshaft of the engine is transmitted to the axle. Therefore, the overall efficiency indicating how much power is output on the axle with respect to the fuel injection and the fuel amount can be approximated with relatively high accuracy as a multiplication value thereof. Then, the compression ratio ε that maximizes the overall efficiency thus determined, that is, optimizes the overall efficiency, is selected. Specifically, the compression ratio ε corresponding to the maximum value of the overall efficiency in the graph 904 is selected (step S14).
[0100]
Thereafter, the compression ratio optimization logic by the interrupt process is terminated.
[0101]
As described above, under the control of the control unit 190 and the EFIECU 170, the compression ratio ε, the engine speed Ne, and the engine torque Te as the combination of the operating point parameters are set in accordance with the driving state such as the current vehicle speed and the accelerator depression amount. Information such as these operating point parameters set is transmitted from the control unit 190 to the EFIECU 170, and the engine 150 and the variable compression ratio device (see FIGS. 6 to 14) are controlled by the EFIECU 170, and the engine At 150, the operating state such as the fuel injection amount or the throttle opening is controlled. In parallel with this, in motor generators MG1 and MG2, their rotational speeds are controlled by collinear charts as shown in FIGS. 2 and 3 or so-called proportional integral control (PI control). More specifically, the motor generators MG1 and MG2 are controlled by setting, for example, voltages to be applied to the three-phase coils of each motor in accordance with the set engine speed Ne and engine torque Te. The transistors of the drive circuits 191 and 192 are switched according to the deviation.
[0102]
As described above, the combination that optimizes the overall efficiency among the combinations of the compression ratio ε, the engine speed Ne, and the engine torque Te as the plurality of operating point parameters is selected in real time during the operation of the hybrid vehicle. Become. Since the engine 150 and the motor generator device are operated according to the compression ratio ε, the engine speed Ne, and the engine torque Te selected in this way, the engine efficiency itself is not maximized, but the overall efficiency is improved. It is operated in a state of being maximized or in a state close to the state of being maximized. According to the conventional technique, as shown in the graph 902 shown in the upper part of FIG. 17, selection and control for maximizing the engine efficiency are performed in consideration of only the engine efficiency. The overall efficiency as shown in the graph 904 shown cannot be maximized. Furthermore, as can be seen from the graphs 902 to 904 in FIG. 17, each efficiency changes sensitively with respect to the change in the compression ratio ε, so that the overall efficiency is significantly reduced in the control focusing only on the engine efficiency. There are many cases of inviting.
[0103]
As described above, according to the optimization method of the present embodiment, the overall efficiency of the hybrid vehicle can be increased.
[0104]
(Deformation)
In the case of the configuration as in the above-described embodiment, the hybrid vehicle is regenerated by the MG 2 at the time of deceleration. decreasing. In particular, when the compression ratio ε increases, the friction torque of the pumping portion when the engine 150 is rotated increases, and among these, the resistance when compressing the air in the combustion chamber becomes so large that it cannot be ignored. On the other hand, ideally, if the compression ratio ε = 0 in the combustion chamber of the engine can be set only at the time of regeneration, the friction torque should be able to be made only by the mechanical part even in the compression process.
[0105]
Therefore, in this modified embodiment, when the vehicle deceleration energy is regenerated by the motor generator, the compression ratio ε is reduced to reduce engine friction (pumping friction). More specifically, when the deceleration state is detected by the vehicle speed sensor, the acceleration sensor, or the like under the control of the control unit 190 and the EFIECU 170, or when the motor generator is detected to be in the regenerative state, the compression ratio The engine 150 and the variable compression ratio device (see FIGS. 6 to 14) are controlled so as to reduce ε. In the engine 150, the operation state such as the fuel injection amount or the throttle opening is controlled. .
[0106]
As a result of the above, according to the present modification, the compression ratio ε is reduced during regeneration of the motor generator device, so that the friction torque due to the pumping operation in the engine 150 can be reduced, and the regeneration efficiency in the motor generator device is improved. It is done. As a result, the overall efficiency of the entire power output system or the entire hybrid vehicle can be further improved.
[0107]
In addition, more preferably, during such regeneration, the fuel for the engine 150 is cut, that is, fuel injection or fuel supply is temporarily stopped. In order to reduce the compression ratio ε, the intake valve and the exhaust valve of the engine 150 may be temporarily fixed in an open state. As a result, at the time of regeneration, the engine 150 is simply brought into a state of being rotated, so that further improvement in fuel consumption can be achieved.
[0108]
(Other variations)
As the configuration of the hybrid vehicle to which the present invention is applied, various configurations are possible in addition to the configuration shown in FIG.
[0109]
In the above-described embodiment, the motor generator MG2 is coupled to the ring gear shaft 126 as shown in FIG. 1, but the motor generator MG2 is coupled to the planetary carrier shaft 127 directly coupled to the crankshaft 156 of the engine 150. You can also take Alternatively, in FIG. 1, a mechanical distribution type power adjustment device using the planetary gear 120 or the like is used as a power adjustment device for transmitting a part of the power output from the engine 150 to the drive shaft 112. As the adjusting device, it is also possible to use an electric distribution type power adjusting device using a counter rotor electric motor or the like. For example, instead of planetary gear 120 and motor generator MG1, a clutch motor CM may be provided.
[0110]
For example, even in a specific example of the parallel hybrid system as described below with reference to FIGS. 18 and 19, an engine compression ratio optimization method similar to the above-described embodiment is possible. Can provide similar or similar technical effects. FIG. 18 is a block diagram showing a schematic configuration of a power output system in one specific example, and FIG. 19 is a characteristic diagram showing how the compression ratio is optimized.
[0111]
As shown in FIG. 18, in this specific example, the output of the engine 150 is transmitted directly to the motor generator MG 201, and the output is further transmitted to the axle via a CVT (Constantly Valuable Transmission) 202 and a differential gear (DF gear) 203. Is output. In the case of such a configuration, as shown in FIG. 19, the same required power generation amount (that is, “equal Pe line”) according to the use area of the engine on the characteristic diagram, that is, the operating point selection location. Thus, the power generation torque in motor generator MG201 is different. This is because in the case of motor generator MG201 directly connected to engine 150, the rotational speed of the motor generator is always equal to the engine rotational speed. As described above, in this specific example, the power generation efficiency of the motor generator MG201 differs depending on the use range of the engine. Therefore, the overall efficiency is approximated by the multiplication value of the engine efficiency and the power generation efficiency of the motor generator, and this is maximized. If the compression ratio ε is selected, the overall efficiency can be increased as in the above-described embodiment.
[0112]
Also, for example, in another specific example of the serial hybrid system as described below with reference to FIGS. 20 to 22, an engine compression ratio optimization method similar to the above-described embodiment is possible. This provides a similar or similar technical effect. Here, FIG. 20 is a block diagram showing a schematic configuration of a power output system in another specific example, and FIG. 21 shows the state of the rotation speed Np on the axle (propeller shaft) and the axle showing the state of optimization of the compression ratio. FIG. 22 is a characteristic diagram showing the relationship of the upper torque Tp, and FIG. 22 is another characteristic chart showing how the compression ratio is optimized.
[0113]
As shown in FIG. 20, in this specific example, the output of the engine 150 is transmitted to a motor generator 302 via a transmission (T / M) 301 such as manual or automatic. Further, the output is output to the axle via a differential gear (DF gear) 303. The characteristic diagrams of FIGS. 21 and 22 respectively show the engine WOT line (“EngWOT line”) on the peller shaft (propeller shaft or axle) when the transmission 301 is a low gear, and the peller when the transmission 301 is a high gear. The on-axis engine WOT line is shown.
[0114]
In this specific example, for example, as shown in FIG. 21, the required driving force (shown as “required peller shaft power” in FIG. 21) that is larger than the engine torque on the WOT line of the engine 150 when the transmission 301 is set to the high gear. When the driving force corresponding to the operating point is required, instead of shifting down the transmission 301 (changing to low gear), the motor generator 302 assists and the overall efficiency is maximized on the assumption that this assist is performed. The compression ratio ε1 to be selected is selected. Here, the currently selected compression ratio ε is reduced to ε1. Thereby, the fuel efficiency can be improved by outputting the required driving force. Alternatively, in this specific example, as shown in FIG. 22, for example, when a required driving force larger than the engine torque on the WOT line of the engine 150 when the transmission 301 is set to the high gear is required, the transmission 301 is shifted down. In addition, the compression ratio ε2 that maximizes the overall efficiency is selected on the assumption that the motor generator 302 does not assist and does not assist. Here, the currently selected compression ratio ε is reduced to ε2. Thereby, the fuel efficiency can be improved by outputting the required driving force. In the case of a traditional engine system that does not have the motor generator 302, in this case, the transmission must be downshifted, resulting in a reduction in fuel consumption. On the other hand, in this specific example shown in FIG. 20 to FIG. 22, fuel consumption can be improved by not performing an operation with a large energy loss such as downshifting of the transmission 301. In addition, the compression ratio ε1 shown in FIG. 21 may be always selected for the same required driving force, or the compression ratio ε2 shown in FIG. 22 may be selected. Of the ratio ε1 and the compression ratio ε2, the one with higher overall efficiency may be selected.
[0115]
As described above, in this specific example, in addition to the compression ratio ε as the operating point parameter, the assist amount of the motor generator 302 and the gear ratio in the transmission 301 are used, and the optimum combination that maximizes the overall efficiency is selected as a combination thereof. As a result, the overall efficiency can be increased as in the above-described embodiment.
[0116]
In the above-described embodiment, the motor generator device includes a plurality of motor generators composed of synchronous motors, but instead of or in addition to at least a part of them, an induction motor, a vernier motor, a DC motor, a superconducting motor, a step motor, etc. It is also possible to use.
[0117]
In the above-described embodiment, a direct-injection type gasoline engine operated by gasoline is used as the engine 150. In addition, various other types such as a traditional port-injection type gasoline engine, a diesel engine, a turbine engine, and a jet engine are used. An internal combustion engine or an external combustion engine can be used.
[0118]
However, in any engine, compression ratio variable means similar to or different from the variable compression ratio device described above is provided.
[0119]
In addition, the hybrid vehicle control device of the present invention may be applied to various parallel hybrid type and various serial hybrid type vehicles that are already existing, are currently being developed, or will be developed in the future.
[0120]
The present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist or concept of the invention that can be read from the claims and the entire specification, and a hybrid vehicle with such a change The control device and method and the hybrid vehicle including such a control device are also included in the technical scope of the present invention.
[0121]
【The invention's effect】
As described above in detail, according to the present invention, in the hybrid vehicle, not only the engine efficiency related to the engine but also the power generation efficiency related to the motor generator device, the electric efficiency, and the power including the transmission efficiency in the transmission mechanism, etc. The overall efficiency of the entire output system or the entire hybrid vehicle can be increased.
[Brief description of the drawings]
FIG. 1 is a block diagram of a power system in a hybrid vehicle according to an embodiment of the present invention.
FIG. 2 is a collinear diagram for explaining a basic operation of the hybrid vehicle according to the present embodiment.
FIG. 3 is a collinear diagram when the hybrid vehicle according to the present embodiment is traveling at a high speed in a steady state.
FIG. 4 shows a configuration of a battery and a motor drive circuit of the hybrid vehicle according to the present embodiment.
FIG. 5 is a schematic configuration diagram of a structure of an engine according to the present embodiment.
FIG. 6 is a partial cross-sectional side view of a variable compression ratio device that can be used in the present embodiment.
FIG. 7 is an enlarged view of a part of FIG. 6;
8 is an axial partial cross-sectional view (part 1) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
9 is an axial partial cross-sectional view (part 2) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
10 is a partial axial sectional view (part 3) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
11 is a partial axial sectional view (part 4) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
12 is an axial partial cross-sectional view (part 5) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
13 is an axial partial cross-sectional view (part 6) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
14 is an axial partial cross-sectional view (part 7) showing the relative rotational positional relationship among the connecting rod, the crankpin, and the eccentric bearing according to the variable compression ratio device shown in FIG. 6 over time;
FIG. 15 is a characteristic diagram schematically showing how the engine WOT line changes when the compression ratio is changed in the engine compression ratio optimization method of the present embodiment.
FIG. 16 is a flowchart showing an engine compression ratio optimization method according to the present embodiment.
FIG. 17 is a conceptual diagram schematically showing how various efficiencies with respect to changes in the compression ratio in the main steps change in the engine compression ratio optimization method of the present embodiment.
FIG. 18 is a block diagram showing a schematic configuration of a power output system in a specific example of a parallel hybrid system as a modification of the present embodiment.
FIG. 19 is a characteristic diagram showing how the compression ratio is optimized in the specific example shown in FIG. 18;
FIG. 20 is a block diagram showing a schematic configuration of a power output system in another specific example of the serial hybrid system as a modification of the present embodiment.
FIG. 21 is a characteristic diagram showing the relationship between the rotational speed Np on the axle and the torque Tp on the axle, showing how the compression ratio is optimized in the specific example shown in FIG. 20;
FIG. 22 is another characteristic diagram showing the relationship between the rotational speed Np on the axle and the torque Tp on the axle, showing how the compression ratio is optimized in the specific example shown in FIG. 20;
[Explanation of symbols]
120 Planetary gear
150 engine
170 EFIECU
190 Control unit (ECU)
194 battery
MG1, MG2 motor generator
578 Accelerator pedal
580 Accelerator opening sensor

Claims (9)

(i) The engine, the compression state variable means capable of changing the compression state in the combustion chamber of the engine, and at least a part of the output of the engine can be used to generate electric power and the driving force can be output via the drive shaft. A hybrid type power output system including a motor generator device, (ii) a vehicle main body on which the power output system is mounted, and (iii) the drive attached to the vehicle main body and output through the drive shaft A control device for controlling a hybrid vehicle having wheels driven by force,
A plurality of pre-set operations of the power output system including the compression state, which are preset to achieve the required driving force required for the power output system according to a plurality of types of driving states assumed in the hybrid vehicle. A selection means for selecting, as an optimal combination, a plurality of combinations of the parameters, which maximizes the overall efficiency of the power output system in accordance with an actual driving state;
Control means for controlling at least the compression state variable means so as to achieve the compression state in the selected optimal combination,
The compression state variable means can change a compression ratio in the combustion chamber as the compression state,
The power output system further includes a power storage device that can be charged by the motor generator device and can supply power to the motor generator device,
The control means controls the compression state varying means so as to reduce the compression ratio when the motor generator device charges the power storage device for regeneration .   The plurality of parameters further includes an engine speed and an engine torque of the engine,
  2. The hybrid vehicle control device according to claim 1, wherein the control unit further controls the engine so that the engine speed and the engine torque in the selected optimal combination are obtained. 3.   In the energy recirculation mode, the control means achieves the same driving force with the engine throttle fully open when the overall efficiency is reduced due to the rotation speed of the motor generator device shifting from positive to negative. 3. The hybrid according to claim 2, wherein the engine and the compression state variable unit are controlled so as to return the rotational speed of the motor generator device from negative to positive by increasing the engine rotational speed. Vehicle control device. (i) The engine, the compression state variable means capable of changing the compression state in the combustion chamber of the engine, and at least a part of the output of the engine can be used to generate electric power and the driving force can be output via the drive shaft. A hybrid type power output system including a motor generator device, (ii) a vehicle main body on which the power output system is mounted, and (iii) the drive attached to the vehicle main body and output through the drive shaft A control device for controlling a hybrid vehicle having wheels driven by force,
A plurality of pre-set operations of the power output system including the compression state, which are preset to achieve the required driving force required for the power output system according to a plurality of types of driving states assumed in the hybrid vehicle. A selection means for selecting, as an optimal combination, a plurality of combinations of the parameters, which maximizes the overall efficiency of the power output system in accordance with an actual driving state;
Control means for controlling at least the compression state variable means so as to achieve the compression state in the selected optimal combination,
The compression state variable means can change a compression ratio in the combustion chamber as the compression state,
The plurality of parameters further includes an engine speed and an engine torque of the engine,
The control means further controls the engine so as to be the engine speed and the engine torque in the selected optimal combination,
In the energy recirculation mode, the control means achieves the same driving force with the engine throttle fully open when the overall efficiency is reduced due to the rotation speed of the motor generator device shifting from positive to negative. However, the hybrid vehicle control apparatus controls the engine and the compression state variable means so as to return the rotational speed of the motor generator device from negative to positive by increasing the engine rotational speed . The power output system further includes a transmission mechanism having a planetary gear for selectively transmitting the output of the engine to the drive shaft and the motor generator device and selectively transmitting the output of the motor generator device to the drive shaft. Including
The overall efficiency, the control device for a hybrid vehicle according to claim 1, any one of 4, characterized in that it is approximated by the multiplication value of the engine efficiency in the engine and the system transmission efficiency in the transmission mechanism. The power output system further includes a transmission mechanism for transmitting the output of the engine directly to the motor generator device and transmitting the output of the motor generator device to the drive shaft,
The overall efficiency, the control device for a hybrid vehicle according to claim 1, any one of 4, characterized in that it is approximated by the multiplication value of the engine efficiency in power generation efficiency and the engine in the motor-generator device. The power output system further includes a transmission mechanism for transmitting the output of the engine to the motor generator device via a transmission and transmitting the output of the motor generator device to the drive shaft.
The hybrid vehicle according to any one of claims 1 to 4, wherein the plurality of parameters further include a gear ratio in the transmission and an assist amount by the motor generator device in addition to the compression state. Control device. Control device according to any one of claims 1 to 7, and the power output system, a hybrid vehicle, comprising the said vehicle body and the wheel. (i) The engine, the compression state variable means capable of changing the compression state in the combustion chamber of the engine, and at least a part of the output of the engine can be used to generate electric power and the driving force can be output via the drive shaft. A hybrid type power output system including a motor generator device, (ii) a vehicle main body on which the power output system is mounted, and (iii) the drive attached to the vehicle main body and output through the drive shaft A control method for controlling a hybrid vehicle having wheels driven by force,
A plurality of pre-set operations of the power output system including the compression state, which are preset to achieve the required driving force required for the power output system according to a plurality of types of driving states assumed in the hybrid vehicle. A selection step of selecting, as an optimal combination, a plurality of combinations of parameters that maximizes the overall efficiency of the power output system in accordance with an actual operating state;
A control step of controlling at least the compression state variable means so as to achieve the compression state in the selected optimal combination,
The compression state variable means can change a compression ratio in the combustion chamber as the compression state,
The power output system further includes a power storage device that can be charged by the motor generator device and can supply power to the motor generator device,
The method for controlling a hybrid vehicle, wherein the control step controls the compression state variable means so as to reduce the compression ratio when the motor generator device charges the power storage device for regeneration .

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