JP2017019393A - On-vehicle control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an on-vehicle control device that can restart a stopped engine when an acceleration request by a driver occurs, and perform smooth acceleration when a clutch between the engine and an automatic transmission is fastened.SOLUTION: When an acceleration request by a driver occurs, a stopped engine is restarted, and a power transmission mechanism between the engine and wheels is fastened to accelerate a vehicle. A target transmission gear ratio of a transmission at least according to an acceleration operation amount is obtained, and a transmission gear ratio after a restart condition is established is controlled based on the target transmission gear ratio. According to this, by appropriately controlling the target transmission gear ratio of the transmission based on the driver's acceleration operation amount, it is possible to acquire smooth acceleration feelings and suppress the deterioration of drivability.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an in-vehicle control device for controlling an automobile, and more particularly to an in-vehicle control device having an automatic stop / restart function for automatically stopping and restarting an engine while the automobile is running.

  In recent years, automobiles equipped with an automatic engine stop / restart control system (hereinafter referred to as vehicles) are increasing for the purpose of improving fuel consumption and reducing exhaust emissions. The conventional general automatic stop / restart control system stops fuel injection and spark ignition when the driver stops the vehicle, automatically stops the engine, and then the driver starts the vehicle. When an operation to be performed (brake release operation, accelerator pedal depression operation, etc.) is performed, the starter or a starter motor is automatically energized to crank the engine and restart it.

  Furthermore, recently, as disclosed in Japanese Patent Application Laid-Open No. 2006-200370 (Patent Document 1), when a predetermined condition is satisfied during traveling, the engine is temporarily stopped and the transmission and the engine or the transmission are also stopped. The power transmission mechanism installed in the power transmission system between the wheel and the wheel is disconnected, the vehicle is driven by inertia, and then the engine is restarted and the clutch is re-engaged when a predetermined condition is met Has been. This can be expected to improve fuel consumption because the engine can be stopped and the vehicle speed can be maintained for a long time without depressing the accelerator pedal.

JP 2006-200370 A

  By the way, when performing inertial driving as disclosed in Patent Document 1, when the driver's accelerator operation, that is, when the driver requests acceleration, the stopped engine is restarted, and the engine and wheels are connected. It is necessary to fasten the vehicle by fastening a power transmission mechanism in between. However, at this time, the gear ratio is not controlled to an appropriate gear ratio at the time of restart corresponding to the accelerator operation, and there is a problem that the accelerator response is deteriorated and the drivability is adversely affected.

  In particular, in order to attach importance to the reduction of fuel consumption, when the engine is operated with an output torque that can increase fuel consumption, there is a problem that the accelerator response is further deteriorated. In any case, there is a strong demand for improving the accelerator response when the engine is restarted and accelerated from the state where the engine is stopped and coasting, that is, smooth acceleration can be achieved.

  An object of the present invention is to perform smooth acceleration when restarting an engine that has been stopped and fastening a power transmission mechanism between the engine and wheels when a driver requests acceleration. It is to provide a new in-vehicle control device that can perform the above-mentioned.

  The feature of the present invention is that when an acceleration request is generated by the driver, the stopped engine is restarted, and the vehicle is accelerated by fastening a power transmission mechanism between the engine and the wheel, and at least an accelerator operation is performed. The target gear ratio of the transmission according to the amount is obtained, and the gear ratio after the restart condition is established is controlled based on the target gear ratio.

  According to the present invention, when the vehicle is accelerated by starting the engine and fastening the power transmission mechanism between the engine and the wheels from the inertial running state in which the engine is stopped, the speed is changed based on the accelerator operation amount of the driver. By appropriately controlling the target gear ratio of the aircraft, it is possible to obtain a smooth feeling of acceleration and suppress deterioration of drivability.

It is a block diagram which shows the structure of the motor vehicle carrying the vehicle-mounted control apparatus with which this invention is applied. It is a block diagram which shows the internal structure of a vehicle-mounted control apparatus. It is a control block diagram which shows the structure of the specific control block of the automatic stop / restart means provided in the vehicle-mounted control apparatus which becomes embodiment of this invention. It is explanatory drawing explaining the relationship between an engine speed, an engine torque, an equal output line, an equal fuel consumption line, and an optimal fuel consumption line. It is a flowchart figure which shows the specific control flow of the engine automatic stop determination means in the control block shown in FIG. It is a flowchart figure which shows the specific control flow of the engine restart request | requirement determination means in the control block shown in FIG. It is a flowchart figure which shows the specific control flow of step 603 of the control flow shown in FIG. FIG. 4 is a flowchart showing a specific control flow during automatic engine stop of the target gear ratio calculation means in the control block shown in FIG. 3. FIG. 4 is a flowchart showing a specific control flow at the time of restart of a target gear ratio calculation means in the control block shown in FIG. 3. It is a flowchart figure which shows the concrete control flow of step 803,903 of the control flow shown in FIG. 8, FIG. It is a flowchart figure which shows the concrete control flow by the throttle valve of the filling efficiency control means in the control block shown in FIG. It is a flowchart figure which shows the specific control flow by the intake valve of the filling efficiency control means in the control block shown in FIG. It is a flowchart figure which shows the concrete control flow at the time of the restart of the fuel injection quantity control means of the control block shown in FIG. FIG. 4 is a flowchart showing a specific control flow at the time of restarting an ignition timing control means in the control block shown in FIG. 3.

  Embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the following embodiments, and various modifications and application examples are included in the technical concept of the present invention. It is included in the range. Hereinafter, the configuration and operation of the in-vehicle control apparatus according to the embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 shows the overall configuration of a vehicle equipped with an in-vehicle control device to which the present invention is applied. The vehicle 10 has an engine main body 11 (also simply referred to as an internal combustion engine or an engine) as a driving force source, and a torque converter 12 is provided on the output side of the engine 11. An automatic transmission 13 is connected to the output side of the torque converter 12. The type of the engine 11 may be a driving force source that causes the vehicle 10 to travel, and examples thereof include a port injection type or in-cylinder injection type gasoline engine, a diesel engine, and the like. The structure of the engine 11 may be a Wankel rotary engine in addition to a reciprocating engine.

  In addition, the engine 11 is provided with a starter 14 and a power generator 15 that supplies electric power to the vehicle 10. As the starter 14, for example, a starter motor including a DC motor, a gear mechanism, and a gear pushing mechanism can be used. The starter 14 is driven by electric power supplied from the power supply 16 and starts the engine 11 based on the start request.

  As the power supply 16, for example, a lead battery can be suitably used, and various secondary batteries including a lithium ion secondary battery, and a capacitor such as a capacitor may be used. Moreover, as the electric power generating apparatus 15, the alternator which consists of an induction generator, a rectifier, and a voltage adjustment mechanism can be used, for example. The power source 16 stores the electric power generated by the power generation device 15 and supplies the electric power to the starting device 14 and vehicle electrical components such as a headlight (not shown) and various controllers.

  Further, the engine 11 has a crankshaft 17, one of the crankshafts 17 has a signal plate 18 engraved with a predetermined pattern for detecting a crank angle signal, and the other has a driving force to the transmission. A ring gear integral with a drive plate (not shown) for transmission is attached.

  A crank angle sensor 19 that detects the unevenness of the pattern and outputs a pulse signal is attached in the vicinity of the signal plate 18. Based on the pulse signal output from the crank angle sensor 19, an engine control unit (hereinafter referred to as the engine control unit) The ECU 20 calculates the rotational speed of the engine 11 (engine rotational speed).

  As intake system components of the engine 11, an intake manifold 21, a throttle valve 22, an air flow sensor 23, and an air cleaner 24 that distribute intake air to each cylinder are attached.

  The throttle valve 22 is an electronically controlled throttle device. The vehicle speed sensor 30 detects the speed of the vehicle from the signal of the accelerator pedal sensor 26 that detects the amount of depression of the accelerator pedal 25, the signal of the brake switch 28 that detects the amount of depression of the brake pedal 27, and the rotational speed of the drive wheels 29. The ECU 20 calculates the optimum throttle opening based on the signal of the above and other signals sent from each sensor, and based on the calculated output, the optimal throttle valve opening is obtained by an electronically controlled throttle device. Controlled.

  The air flow sensor 23 measures the air flow rate sucked from the air cleaner 24 and outputs it to the ECU 20. In the ECU 20, a fuel amount corresponding to the measured air amount is calculated and output to the fuel injection valve 31 as a valve opening time. The valve opening start timing starts injection at a timing preset by the ECU 20 based on a signal from the crank angle sensor 19.

  By this operation, the intake air and the fuel injected from the fuel injection valve 31 are mixed in the cylinder of the engine 11 to form an air-fuel mixture. The timing for igniting the air-fuel mixture is also preset by the ECU 20 based on the signal from the crank angle sensor 19, and the high voltage generated by the ignition coil 32 is applied to the spark plug 33 to ignite the air-fuel mixture in the cylinder. It burns and explodes.

  The engine 11 transmits kinetic energy obtained by combustion and explosion to the crankshaft 17 to generate a rotational driving force. A drive plate (not shown) is attached to the transmission side of the crankshaft 17 and is directly connected to the input side of the torque converter 12.

  On the other hand, the output side of the torque converter 12 is input to the transmission 13. The transmission 13 is a transmission main body having a stepped transmission mechanism or a belt-type or disk-type continuously variable transmission mechanism, and is controlled by a transmission control unit (hereinafter referred to as TCU) 34 to obtain engine information (engine rotation). Number, vehicle speed, throttle opening, etc.) and gear range information 36 of the gear shift lever 35, an appropriate gear ratio or gear ratio is determined to control the gear ratio to the optimum.

  The gear ratio can be controlled by controlling the hydraulic pressure of the transmission supplied from the mechanical oil pump 37 while the engine 11 is being driven. Further, the engine 11 can be stopped by controlling the hydraulic pressure of the transmission supplied from the electric oil pump 38.

  A clutch mechanism 40 is provided between the transmission 13 and the differential mechanism 39. When the driving force from the transmission 13 is transmitted to the differential mechanism 39 to drive the drive wheels 29, the clutch mechanism 40 is provided. When 40 is fastened and the reverse driving force from the driving wheel 39 is interrupted, the clutch mechanism 40 is opened and control is performed so that the reverse driving force is not transmitted to the transmission 13. The clutch mechanism 40 may be provided between the engine 11 and the transmission 13.

  When the vehicle 10 is traveling in a coasting state, the clutch mechanism 40 is opened to cut off the reverse driving force, and the engine 10 is stopped, thereby creating a state in which the traveling resistance is reduced as much as possible. This can improve fuel consumption.

  FIG. 2 is an example of an internal configuration of the in-vehicle control device according to the present embodiment. In this embodiment, the ECU 20 is handled as a part of the in-vehicle control device. Therefore, in this embodiment, the vehicle-mounted control device is a combination of the ECU 20 and the TCU 34.

  In the ECU 20, an electric signal of each sensor installed in the engine 11 is converted into a signal for digital arithmetic processing inside a CPU (Central Processing Unit) 200, and a control signal for digital arithmetic is driven to an actual actuator. An I / O (Input / Output) unit 201 for converting signals is provided. The I / O unit 201 includes a crank angle sensor 19, an intake air amount sensor 23, an intake pipe pressure sensor 41, a vehicle speed sensor 30, an accelerator. Signals from the pedal opening sensor 26, the ignition switch 42, the brake switch 28, the throttle opening sensor 43, the intake valve phase sensor 44, and the exhaust valve phase sensor 45 are input.

  On the other hand, an output signal from the CPU 200 is output to the fuel injection valves 31-1 to 31-4, the ignition coils 32-1 to 32-4, the throttle valve drive motor 46, and the intake valve hydraulic actuator 47 via the drive circuit 202. Will be sent. The intake valve hydraulic actuator 47 controls the amount of oil sent to the vane chamber of the vane type intake valve phase control device and the destination of the oil.

  FIG. 3 shows the configuration of the control block of the automatic stop / restart means according to the present embodiment provided in the ECU 20.

  Block 301 is an engine automatic stop determination means. This engine automatic stop determination means 301 includes ignition switch information, vehicle speed information, power transmission mechanism information obtained from the output of the TCU 34, accelerator pedal depression amount information (hereinafter referred to as accelerator pedal depression amount). Is expressed as an accelerator pedal opening), brake switch information, and engine restart request determination information determined in block 303 (engine restart request determining means) described later, automatic engine stop is determined. The power transmission mechanism information is based on the power transmission mechanism cutoff / engagement request determination information determined by a block 306 (power transmission mechanism cutoff / engagement request determination means) described later. Information about blocking.

  Block 302 is system restart request determination means. This system restart request determination means 302 determines a system restart request. During automatic engine stop, (1) when performance degradation or abnormality is detected in the system components or functions of the vehicle, (2 ) When an air conditioner operation request is generated, (3) When a power generation request is generated, (4) When a vehicle deceleration increase request is generated for avoiding a collision with an object ahead of the vehicle based on external world recognition information In this case, it is determined whether at least one of the drivers needs to start the engine other than the accelerator pedal operation.

  Block 303 is engine restart request determination means. The engine restart request determination means 303 issues an engine restart request based on engine automatic stop determination information, brake switch information, accelerator pedal opening information, power transmission mechanism information obtained from the output of the TCU 34, and system restart request determination information. Judgment.

  Block 304 is a target engine speed calculation means. The target engine speed calculating means 304 calculates a target engine speed from vehicle speed information and target speed ratio information calculated by a block 305 (target speed ratio calculating means) described later. The target engine speed can be calculated based on the engine performance diagram, or a map of the target engine speed centered on the vehicle speed information and the target gear ratio is set in advance. The target engine speed can be obtained from the gear ratio.

  Block 305 is a target gear ratio calculation means. The target gear ratio calculation means 305 calculates a target gear ratio from engine restart request determination information, accelerator pedal opening information, engine automatic stop determination information, vehicle speed information, and gear ratio information obtained from the output of the TCU 34. Here, the target gear ratio information is information relating to the gear ratio controlled by the TCU 34.

  The target gear ratio is transmitted to the TCU 34. The TCU 34 uses the target gear ratio information and the result of the power transmission mechanism cutoff / engagement request determination determined by a block 306 (power transmission mechanism cutoff / engagement request determination means) described later. Based on the information on the engine side (engine speed, vehicle speed, throttle opening) and the information on the transmission side, the optimum gear ratio is controlled.

  A block 306 is a power transmission mechanism cutoff / fastening request determination unit. The power transmission mechanism cutoff / engagement request determination means 306 determines a power transmission mechanism cutoff / engagement request from the engine automatic stop determination information and the engine restart request determination information. In the power transmission mechanism cutoff / fastening request determination means 306, along with the automatic stop of the engine 11, (1) whether or not there is a request to stop the power transmission mechanism between the engine 11 and the wheels 29 and cause the vehicle to coast by inertia. Alternatively, (2) when the engine is restarted, it is determined whether or not there is a request for accelerating the vehicle by fastening the power transmission mechanism.

  The determination result by the power transmission mechanism cutoff / engagement request determination means 306 is transmitted to the TCU 34 as described above, and the TCU 34 includes information on the engine side (engine speed, vehicle speed, throttle opening) including the determination result. Further, the power transmission mechanism is controlled based on the information on the transmission side.

  Block 307 is a filling efficiency control means. The charging efficiency control means 307 is configured to calculate the engine from the intake valve phase (or the exhaust valve phase), engine restart request determination information, intake air amount information, intake pipe pressure information, engine speed information, and accelerator pedal opening information. The charging efficiency of the intake air supplied to the engine is controlled. Then, the operation amounts of the throttle valve drive motor, the intake valve hydraulic actuator, and the like necessary for controlling the charging efficiency for obtaining the necessary output at the time of restart are determined. As a result, the throttle valve drive motor and the intake valve hydraulic actuator are controlled so as to increase the charging efficiency in order to improve the acceleration performance at the time of restart.

  In the charging efficiency control means 307, when the charging efficiency is controlled by operating the throttle valve drive motor, a wide control range can be obtained, and when the charging efficiency is controlled by operating the intake valve hydraulic actuator, quick response control is possible. Therefore, it is preferable to operate by appropriately using such features. Further, the charging efficiency may be controlled by controlling at least one of EGR gas, purge gas, supercharging pressure, and the like.

  Block 308 is a fuel injection amount control means. This fuel injection amount control means 308 calculates the fuel injection amount from engine automatic stop determination information, intake air amount information, intake pipe pressure information, engine speed information, and engine restart request determination information. Then, the required operation amount and injection timing of the fuel injection valve are determined. Here, since the charging efficiency is increased by the charging efficiency control means 307 at the time of restart, the fuel injection amount is set to be large correspondingly.

  Block 309 is an ignition timing control means. The ignition timing control means 309 controls the ignition timing based on engine speed information, target engine speed information, and engine restart request determination information. Then, a required operation amount (for example, ignition timing) of the ignition coil is determined. Also in this case, since the target engine speed is obtained from the target gear ratio, the ignition timing is determined correspondingly.

  FIG. 4 shows an operation region based on the output engine torque based on the speed ratio controlled when the engine is restarted. The horizontal axis represents the engine speed and the vertical axis represents the engine torque. Based on the engine speed and the engine torque, an equal fuel consumption line 401 connecting regions of equal fuel consumption rates, and a line 402 is an optimum fuel consumption from the equal fuel consumption line 401, that is, an optimal fuel consumption that minimizes the fuel consumption rate. Line 402. A line 403 is an engine equal output line 403.

  In restarting the engine, when the target engine output after restart is the target engine output 403T, conventionally, the engine torque of the line 404 indicated by a broken line that traces the optimum fuel consumption line 402 is realized. However, when the driver operates the accelerator pedal, that is, when an acceleration request is generated, the requested acceleration may not be realized with the engine torque 404, and the accelerator response is deteriorated.

  On the other hand, in this embodiment, the gear ratio is controlled based on the required accelerator amount with respect to the conventional engine torque 404, and the engine torque in the region 405 is realized. With this control, when the accelerator demand at engine restart is small, that is, when the driver's acceleration demand is small, the engine torque 404 can be realized and further the gear ratio can be controlled to improve fuel efficiency. become.

  On the other hand, when the accelerator request amount at the time of engine restart is large, that is, when the driver's acceleration request amount is large, the accelerator response can be improved by realizing the engine torque of the line 406 and further controlling the gear ratio, It becomes possible to prevent deterioration of drivability.

  A specific method for improving the accelerator response when the driver's acceleration demand is large will be described below.

  FIG. 5 is an example of a flowchart of the engine automatic stop determination unit 301 shown in FIG. This flowchart is started by interruption every predetermined time.

  First, in step 501, ignition switch information, vehicle speed information, power transmission mechanism information, accelerator pedal opening information, and brake switch information are read.

  In step 502, it is determined whether or not the ignition switch is ON. If the determination is satisfied, the process proceeds to step 503 described later, and otherwise, the process proceeds to step 510 described later.

  In step 503, it is determined whether or not the vehicle speed is equal to or higher than a predetermined value A. If the determination is satisfied, the process proceeds to step 504 described later, and otherwise the process proceeds to step 510 described later. For example, the predetermined value A is set to a value for determining that the vehicle is to be sexed by automatically stopping the engine and shutting off the power transmission mechanism between the engine and the wheels.

  In step 504, it is determined whether or not the brake switch is OFF. If the determination is satisfied, the process proceeds to step 505 described later, and otherwise, the process proceeds to step 510 described later.

  In step 505, the accelerator pedal OFF elapsed time is calculated from the change in the accelerator pedal opening. The elapsed time is reset to 0 when the accelerator pedal is turned on, and time measurement is started when the accelerator pedal is turned off.

  In step 506, it is determined whether or not the accelerator pedal OFF elapsed time has passed the predetermined time B or more. If the determination is satisfied, the process proceeds to step 507 described below, and otherwise the process proceeds to step 510 described later. The predetermined time B is set to a value for determining that the accelerator pedal OFF state of the driver is not due to the shift to the brake ON, for example. This value is an empirical value.

  In step 507, it is determined from the power transmission mechanism information whether or not the engine and the wheel power transmission mechanism are being cut off. If the determination is satisfied, the process proceeds to step 508 described below, and otherwise the process proceeds to step 510 described later.

  In step 508, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to step 510 which will be described later. Otherwise, the process proceeds to step 509 which will be described later.

  Based on the result of the determination in the above steps, it is determined in step 509 that the engine automatic stop condition is satisfied. On the other hand, in step 510, it is determined that the engine automatic stop condition is not satisfied.

  This determination value is sent to the subsequent engine restart request determination means 303. Further, it is also sent to the target gear ratio calculation means 305, the power transmission mechanism cutoff / engagement request determination means 306, and the fuel injection amount control means 308.

  FIG. 6 is an example of a flowchart of the engine restart request determination means 303, and this flowchart is activated by interruption every predetermined time.

  In step 601, brake switch information, accelerator pedal opening information, power transmission mechanism information, automatic stop determination value information, and system restart request determination value information from the system restart request determination means 302 are read.

  In step 602, it is determined from the determination value determined in the flowchart shown in FIG. 5 whether or not the engine is automatically stopped. If the determination is satisfied, the process proceeds to step 603, which will be described later. Go to 607.

  In step 603, it is determined whether there is an engine output request. This step 603 is executed in another control flow, and details thereof are shown in FIG.

  FIG. 7 is an example of the flowchart of step 603 shown in FIG. 6, and this flowchart is activated by interruption every predetermined time.

  In step 701, it is determined whether or not there is a system restart request from the information of the system restart request determination means 302. If the determination is satisfied, the process proceeds to step 704 described later, and otherwise proceeds to step 702 described later. .

  In step 702, it is determined whether or not the accelerator pedal sensor has been switched from OFF to ON. If the determination is satisfied, the process proceeds to step 704 described later, and otherwise, the process proceeds to step 703 described later.

  In step 703, it is determined whether or not the brake switch has been turned from OFF to ON. If the determination is satisfied, the process proceeds to step 704 described later, and otherwise, the process proceeds to step 705 described later.

  In step 704, it is determined that the engine output request condition is satisfied. In step 705, it is determined that the engine output request condition is not satisfied. These determination values are used in step S603. When this determination value is obtained, the process proceeds to step S604.

  In step 604, it is determined whether there is an engine output request. If the determination is satisfied, the process proceeds to step 605, which will be described later. Otherwise, the process proceeds to step 607, which will be described later.

  In step 605, it is determined from the power transmission mechanism information whether or not the engine and the wheel power transmission mechanism are shut off. If the determination is satisfied, the process proceeds to step 606 described later, and otherwise, the process proceeds to step 607 described later. .

  If all of the above steps are determined as “YES”, it is determined in step 606 that the engine restart request condition is satisfied. On the other hand, in step 607, it is determined that the engine restart request condition is not satisfied.

  This determination value is sent to the subsequent charging efficiency control means 307. Further, it is also sent to the target gear ratio calculation means 305, the power transmission mechanism cutoff / engagement request determination means 306, the fuel injection amount control means 308, and the ignition timing control means 309.

  8 and 9 are examples of a flowchart of the target gear ratio calculation means 305, FIG. 8 is a control flow when the engine is automatically stopped, and FIG. 9 is a control flow when the engine restart is determined. It is. FIG. 8 and FIG. 9 are control flows that characterize the present embodiment. Note that these flowcharts are activated by interruption at regular intervals.

  First, in FIG. 8, at step 801, vehicle speed information, accelerator pedal opening information, transmission ratio information, automatic stop determination value information, and restart request determination value information are read.

In step 802, it is determined whether or not the engine is automatically stopped. If the determination is satisfied, the process proceeds to step 803, which will be described later. Otherwise, the specific process is not performed and the process of this flowchart ends. In step 803, the target gear ratio is calculated. Details of the calculation of the target gear ratio are shown in FIG. The calculated target gear ratio is sent to the TCU 34 to control the actual gear ratio. On the other hand, in FIG. 9, at step 901, vehicle speed information, accelerator pedal opening information, gear ratio information, automatic stop The judgment value information and the start request judgment value information are read.

  In step 902, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to step 903, which will be described later. Otherwise, the specific process is not performed and the process of this flowchart is terminated. In step 903, the target gear ratio is calculated. Details of the calculation of the target gear ratio are also shown in FIG. Then, the calculated target gear ratio is sent to the TCU 34, and the actual gear ratio is controlled.

  FIG. 10 is an example of a flowchart of step 803 of the flowchart of FIG. 8 and step 903 of the flowchart of FIG.

  In step 1001, the basic engine speed is calculated from the vehicle speed information and the gear ratio information. For the basic engine speed, a map with the vehicle speed information and the gear ratio information as axes is set in advance, and the basic engine speed can be obtained from the vehicle speed information and the gear ratio information.

  In step 1002, an engine output based on the basic engine speed and fuel consumption information is calculated. The engine output based on the fuel efficiency information can be obtained based on the basic engine speed and the optimum fuel efficiency line 402 of FIG. Alternatively, the engine output centered on the basic engine speed may be preset as a table, and the engine output retrieved from the basic engine speed may be used.

  In step 1003, a basic target gear ratio is calculated from the engine output obtained based on the basic engine speed and fuel consumption information. For the basic target gear ratio, a map of the basic target speed ratio with the engine output obtained based on the basic engine speed and fuel efficiency information and the vehicle speed information as an axis is set in advance, and the basic target gear ratio is determined from the engine output and vehicle speed information The ratio can be determined.

In step 1004, an accelerator opening gear ratio correction value Km is calculated from the accelerator pedal opening information and the vehicle speed information. For the accelerator opening gear ratio correction value Km, a map of the accelerator opening gear ratio correction value Km with the accelerator pedal opening information and the vehicle speed information as axes is set in advance, and the accelerator opening is determined from the accelerator pedal opening information and the vehicle speed information. In step 1005, the basic target gear ratio is corrected by the accelerator opening gear ratio correction value Km, and is output to the TCU 34 as the target gear ratio. The TCU 34 adjusts and controls the gear ratio according to the target gear ratio.

  For example, when the vehicle speed is low and the amount of depression of the accelerator pedal is large, it is difficult to obtain an acceleration feeling. Therefore, by correcting the basic target gear ratio with the accelerator opening gear ratio correction value Km, it is possible to obtain an acceleration feeling of the gear ratio. Correct in direction. For example, in the case of a stepped transmission, it is possible to obtain a feeling of acceleration by correcting what was conventionally the third speed to the second speed or the first speed. On the other hand, when the amount of depression of the accelerator pedal is small, the correction of the basic target gear ratio taking into account the fuel consumption information is reduced, so that it is possible to earn fuel consumption.

  Thus, in response to the amount of depression of the driver's accelerator pedal, the accelerator response can be improved when the acceleration request amount is large, and further, the fuel efficiency can be improved when the acceleration request amount is small.

  FIGS. 11 and 12 are examples of a flowchart of the charging efficiency control means 307, FIG. 11 is a control flow for obtaining the operation amount of the throttle valve drive motor, and FIG. 12 is a control for obtaining the operation amount of the intake valve hydraulic actuator. It is a flow. These flowcharts are activated by interruption at regular intervals.

  In FIG. 11, in step 1101, accelerator pedal opening information, target engine speed information from the target engine speed calculation means 304, engine speed information, intake pipe pressure information, intake air amount information, restart request determination information, etc. Read.

  In Step 1102, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to Step 1103 described later. Otherwise, the specific process is not performed and the process of this flowchart is terminated.

  In step 1103, the target throttle opening is calculated from the target engine speed and the accelerator pedal opening. For the target throttle opening, a map of target throttle opening with the target engine speed and accelerator pedal opening as axes is set in advance, and the target throttle opening is obtained from the target engine speed and accelerator pedal opening. Yes. Further, for example, a target throttle opening at which the actual engine speed can quickly reach the target engine speed may be set.

  In step 1104, the operation amount of the throttle valve drive motor is calculated from the determined target throttle opening, and the throttle valve opening is adjusted based on the operation amount to control the charging efficiency when the engine is restarted. it can. Here, the charging efficiency is a value obtained by dividing the mass of fresh air sucked into the cylinder of the engine by the air mass in a standard state corresponding to the stroke volume.

  As described above, the charging efficiency of the engine when the restart condition is satisfied is controlled based on the target engine speed and the accelerator opening that reflect the target gear ratio. As a result, the increase in the engine speed after restart can be accelerated, and accordingly, the fastening timing of the power transmission mechanism can be also accelerated, and the accelerator response can be improved.

  Furthermore, the charging efficiency of the engine can be controlled by the opening degree of the throttle valve and the opening / closing timing of the throttle valve. Further, by controlling the charging efficiency by the throttle valve, a wide control range can be obtained.

  Next, the case where the charging efficiency is controlled by the intake valve hydraulic actuator will be described. In FIG. 12, in step 1201, accelerator pedal opening information, target engine speed information, engine speed information, intake pipe pressure information, intake air amount information, restart request determination information, intake valve phase, exhaust valve phase, etc. Read.

  In Step 1202, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to Step 1203 described later. Otherwise, the specific process is not performed and the process of this flowchart is terminated.

  In step 1203, the basic target intake valve phase is calculated from the engine speed and the engine load. As the basic target intake valve phase, a map of the basic target intake valve phase with the engine speed and the engine load as axes is set in advance, and the basic target intake valve phase can be obtained from the engine speed and the engine load.

  The engine load is the intake air pressure measured by an intake air pressure sensor such as a thermal air flow meter or the like converted from the output of the intake pipe pressure sensor installed in the intake pipe into a predetermined process. Can be represented by quantity.

  In step 1204, an intake valve phase correction value Kθ is calculated from the intake valve phase and the exhaust valve phase. As the intake valve phase correction value Kθ, a map of the intake valve phase correction value Kθ about the intake valve phase and the exhaust valve phase is set in advance, and the intake valve phase correction value Kθ is obtained from the intake valve phase and the exhaust valve phase. be able to. For example, it may be set based on the overlap amount of the intake valve and the exhaust valve.

  In step 1205, the basic target intake valve phase is corrected by the intake valve phase correction value Kθ and output as the target intake valve phase.

  In step 1206, the operation amount of the intake valve hydraulic actuator is calculated from the target intake valve phase, and the opening / closing phase of the intake valve is adjusted based on this operation amount to control the charging efficiency when the engine is restarted.

  As described above, the charging efficiency of the engine when the restart condition is satisfied is controlled based on at least one information of the engine speed, engine load, intake valve phase, exhaust valve phase, or a combination of a plurality of information. ing. As a result, the increase in the engine speed after restart can be accelerated, and accordingly, the fastening timing of the power transmission mechanism can be also accelerated, and the accelerator response can be improved.

  Further, the charging efficiency of the engine can be controlled by the opening degree (lift) of the intake valve and the opening / closing phase. Further, by controlling the charging efficiency with the intake valve, it is possible to perform control with quick response.

  The parameters for adjusting the charging efficiency in FIGS. 11 and 12 are not limited to those described above, and it is also possible to adjust the charging efficiency using other parameters.

  FIG. 13 is an example of a flowchart of the fuel injection amount control means 308. This flowchart is activated by interruption every predetermined time.

  In step 1301, the engine speed, the intake air amount, and the intake pipe pressure are read. Subsequently, in step 1302, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to step 1304, which will be described later, and otherwise, the process proceeds to step 1303, which will be described later.

  In step 1303, it is determined whether or not the engine is automatically stopped. If the determination is satisfied, the process proceeds to step 1306 described later. Otherwise, the specific process is not performed and the process of this flowchart is terminated.

  In step 1304, the target fuel injection amount is calculated from the engine speed and the engine load. For the target fuel injection amount, a map of the target fuel injection amount with the engine speed and the engine load as axes is set in advance, and the target fuel injection amount is obtained from the engine speed and the engine load. The engine load is the intake air amount measured by an intake air pressure sensor such as a thermal air flow meter or the like converted from the output of an intake pipe pressure sensor installed in the intake pipe into a predetermined process. Can be represented. In this case, since the charging efficiency is controlled by the lower charging efficiency control means 307, the fuel injection amount is also determined accordingly.

  In step 1305, the fuel injection valve operation amount is calculated from the target fuel injection amount, and the valve opening time of the fuel injection valve is controlled based on this operation amount. In this way, when the restart determination is established, the fuel supply is resumed, and an air-fuel mixture can be generated in the combustion chamber. Here, fuel consumption can be improved by performing fuel supply according to fuel efficiency information based on the optimal fuel efficiency line as required. The fuel consumption information can be obtained from the engine speed and the optimum fuel consumption line of the engine.

  On the other hand, in step 1306, since it is determined that the engine is automatically stopped, the target fuel injection amount is set to 0, the fuel injection valve operation amount is calculated, and the valve opening time of the fuel injection valve is controlled based on this operation amount. . In this case, the valve opening time is not set and the fuel is not injected.

  FIG. 14 is an example of a flowchart of the ignition control means 309, and this flowchart is activated by interruption every predetermined time.

  In step 1401, the engine speed, the intake air amount, and the intake pipe pressure are read. Subsequently, in step 1402, it is determined whether or not there is an engine restart request. If the determination is satisfied, the process proceeds to step 1403 described later. Otherwise, the specific process is not performed and the process of this flowchart is terminated. .

  In step 1403, the target ignition timing is calculated from the engine speed and the target engine speed. For the target ignition timing, a map of the target ignition timing with the engine speed and the target engine speed as axes is set in advance, and the target ignition timing is obtained from the engine speed and the target engine speed. Further, for example, an ignition timing capable of reducing overshoot from the target engine speed may be set for the engine speed increased by the charging efficiency control unit 307 of FIG. In this case, it is possible to suppress the rising of the engine speed after restart, and to speed up the transition of the engine speed to the steady state.

  In step 1404, the operation amount (energization angle, ignition timing) of the ignition coil is calculated from the target ignition timing, and the ignition timing is controlled based on the operation amount. Thus, when the restart determination is established, the air-fuel mixture generated in the combustion chamber can be ignited and the engine can be restarted.

  In addition, although not described in the embodiment, the fastening of the power transmission mechanism between the engine and the wheels when the restart condition is satisfied is one or a combination of the target gear ratio, the vehicle speed, and the engine speed. Thus, the fastening shock can be reduced to reduce the fastening shock.

  Further, in the present embodiment, the ECU 20 and the TCU 34 are configured as separate bodies, but may be configured by combining them together.

  Although there are various technical ideas other than the claims that can be understood from the above-described embodiment, typical ones will be described below.

  (1) The automatic stop / restart means calculates the basic engine speed from the vehicle speed and the gear ratio, calculates the engine output based on the basic engine speed and the fuel consumption information, and calculates the basic target speed ratio from the engine output and the vehicle speed. The speed ratio correction value Km is calculated from the accelerator pedal opening and the vehicle speed, and the target speed ratio is obtained by correcting the basic target speed ratio with the speed ratio correction value Km.

  (2) The automatic stop / restart means includes target engine speed calculation means, calculates the target engine speed from the vehicle speed and the target gear ratio, and the charging efficiency control means calculates from the target engine speed and the depression amount of the accelerator pedal. A target throttle opening is calculated, and the throttle valve is controlled to the target throttle opening to increase the charging efficiency.

  (3) The charging efficiency control means controls the opening degree of the throttle valve or the opening / closing phase of the intake valve.

  (4) The automatic stop / restart means includes target engine speed calculation means, calculates the target engine speed from the vehicle speed and the target gear ratio, and calculates the target ignition timing from the target engine speed and the engine speed. The ignition is performed by the spark plug at the target ignition timing.

  As described above, in the present invention, when the acceleration request by the driver is generated, the stopped engine is restarted, the power transmission mechanism between the engine and the wheels is fastened to accelerate the vehicle, and at least A target speed ratio of the transmission corresponding to the accelerator operation amount is obtained, and the speed ratio after the restart condition is established is controlled based on the target speed ratio.

  According to this, when the vehicle is accelerated by driving the engine and fastening the power transmission mechanism between the engine and the wheels from the inertia running state in which the engine is stopped, the transmission is based on the accelerator operation amount of the driver. By appropriately controlling the target speed ratio, it is possible to obtain a smooth acceleration feeling and suppress deterioration of drivability.

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  DESCRIPTION OF SYMBOLS 10 ... Vehicle, 11 ... Engine, 12 ... Transmission, 19 ... Crank angle sensor, 20 ... ECU (engine control unit), 21 ... Intake manifold, 22 ... Throttle valve, 23 ... Air flow sensor, 35 ... Accelerator pedal, 36 ... Accelerator pedal opening sensor, 37 ... brake pedal, 38 ... brake switch, 39 ... drive wheel, 30 ... vehicle speed sensor, 21 ... fuel injection valve, 22 ... ignition coil, 23 ... ignition plug, 34 ... TCU (transmission control unit) ), 40 ... clutch mechanism, 301 ... engine automatic stop determination means, 303 ... engine restart request determination means, 305 ... target gear ratio calculation means, 307 ... charging efficiency control means, 308 ... fuel injection amount control means, 309 ... ignition Time control means.

Claims (5)

In the vehicle-mounted control device comprising an automatic stop / restart means for automatically stopping or restarting the engine and disconnecting or fastening the power transmission mechanism between the engine and the wheel,
The automatic stop / restart means includes
When an acceleration request is generated by depressing an accelerator pedal in a state where inertial traveling is performed to stop the engine and disconnect the power transmission mechanism, the stopped engine is restarted, and the power transmission mechanism And a target gear ratio of a transmission connected to the engine is determined according to at least a depression amount of the accelerator pedal, and a gear ratio at restart is controlled based on the target gear ratio. In-vehicle control device. The in-vehicle control device according to claim 1,
The in-vehicle control device includes an engine control unit that controls the engine, and a transmission control unit that controls the transmission,
The automatic stop / restart means is provided in the engine control unit, and the information of the target gear ratio obtained by the automatic stop / restart means is sent to the transmission control unit, and the transmission control unit Is a vehicle-mounted control device that controls the transmission gear ratio of the transmission based on the sent target transmission gear ratio. The in-vehicle control device according to claim 2,
The automatic stop / restart means includes a charging efficiency control means for controlling a charging efficiency of intake air supplied to the engine,
The vehicle-mounted control device, wherein the charging efficiency control means controls charging efficiency of intake air supplied to the engine when the engine that has been stopped is restarted and the power transmission mechanism is fastened. The in-vehicle control device according to claim 3,
The on-vehicle control device characterized in that the automatic stop / restart means corrects a basic target speed ratio based on a speed ratio correction value obtained from a depression amount of the accelerator pedal and a vehicle speed to obtain the target speed ratio. The in-vehicle control device according to claim 4,
The in-vehicle control device characterized in that the basic target gear ratio is obtained from an engine output and a vehicle speed.

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