JP2015021419A - Control device for engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device for an engine capable of achieving both of braking performance and accelerating performance under a situation where a master back negative pressure is insufficient.SOLUTION: A control device for an engine includes calculating means 3 for calculating a negative pressure target value Pof a throttle downstream of an intake system 20 when a master back negative pressure Pof a brake booster 43 connected to a throttle upstream in the intake system of an engine 10 is insufficient. The control device further includes supercharging pressure control means 5 for controlling a supercharging pressure which is a pressure on the throttle upstream side of the engine 10 based on the acceleration request requested in the engine 10. The control device furthermore includes throttle control means 6 for controlling a throttle opening TH so as to offset the excess or lack of the negative pressure in the throttle downstream of the intake system 20 caused by change of the supercharging pressure controlled by the supercharging pressure control means 5 while having the negative pressure target value Pas a reference based on the acceleration request requested in the engine 10.

Description

  The present invention relates to a control device for an engine including a braking booster that operates by using negative pressure of an intake system and a supercharger.

  2. Description of the Related Art Conventionally, a negative pressure (vacuum type) brake booster device that assists a depression operation of a brake pedal by using a negative pressure generated in an intake system of an engine is known. In this type of braking booster, a negative pressure (intake manifold pressure) in the intake manifold is introduced into a chamber on one side defined by a power piston interlocked with a brake pedal. Also, atmospheric pressure is introduced into the room on the other side of the power piston as soon as the brake pedal is depressed. As a result, the power piston is urged in the direction from the other side to the one side according to the brake operation, and the brake pedal force is reduced. Note that the negative pressure stored in the chamber on one side of the power piston is also called a master back negative pressure.

  By the way, the master back negative pressure decreases every time the brake pedal is depressed. On the other hand, when the intake manifold pressure becomes lower than the master back negative pressure, the master back negative pressure automatically recovers and a predetermined negative pressure is secured. However, depending on the operating state of the engine, the intake manifold pressure is less likely to be lower than the master back negative pressure, and recovery of the master back negative pressure may be delayed. In particular, in an engine equipped with a supercharger such as a turbocharger or a supercharger, it is difficult to reduce the intake manifold pressure during supercharging.

  In response to such a problem, it has been proposed to reduce the intake manifold pressure by limiting the throttle opening when the master back negative pressure is insufficient. For example, the throttle opening is controlled to be smaller so that the amount of air passing through the throttle valve is smaller than the amount of air sucked into the cylinder of the engine. By such control, the intake manifold pressure is likely to decrease, and the master back negative pressure is easily secured (see, for example, Patent Document 1).

JP 2006-161609

  However, as the throttle opening is decreased, the intake manifold pressure is less likely to increase immediately after the master back negative pressure is recovered. That is, the acceleration performance decreases instead of the brake performance recovering. In particular, when the supercharging pressure is suppressed while the master back negative pressure is insufficient, the time delay until the supercharging pressure rises (supercharging delay) cannot be avoided. As a result, the acceleration of the vehicle decreases. Due to such a decrease in acceleration performance, for example, drive feeling on a road with many curves such as a saddle road is greatly impaired.

  One of the purposes of the present case was invented in view of the above problems, and is to achieve both braking performance and acceleration performance under a situation where the master back negative pressure is insufficient. The present invention is not limited to this purpose, and is a function and effect derived from each configuration shown in the embodiments for carrying out the invention described later, and other effects of the present invention are to obtain a function and effect that cannot be obtained by conventional techniques. Can be positioned.

  (1) The engine control device disclosed herein calculates the negative pressure target value downstream of the intake system throttle when the master boost negative pressure of the brake booster connected downstream of the engine intake system throttle is insufficient. The calculating means to perform is provided. In addition, a supercharging pressure control unit that controls a supercharging pressure that is a pressure upstream of the throttle of the engine based on an acceleration request required for the engine is provided. Further, based on the acceleration request required for the engine, the negative pressure downstream of the intake system throttle caused by the change in the supercharging pressure controlled by the supercharging pressure control means based on the negative pressure target value There is provided throttle control means for controlling the throttle opening of the engine so that the excess or deficiency of the engine is offset.

  For example, the throttle control means preferably controls the throttle opening of the engine based on a value obtained by subtracting the negative pressure target value from the supercharging pressure (or negative pressure downstream of the throttle). Here, the supercharging pressure is based on an acceleration request required for the engine. Therefore, the throttle opening is also based on the acceleration request required for the engine.

“When the master boost negative pressure of the brake booster (brake booster) is insufficient” means “when the internal pressure of the master back exceeds the predetermined pressure and the boosting action of the brake pedal force by the brake booster is weakened. It means "when." The “negative pressure target value” means “a pressure target value for reducing the internal pressure of the master back to less than the predetermined pressure”, and is set to a value at least less than the predetermined pressure.
The “supercharging pressure” is a pressure upstream of the throttle valve provided in the intake system, and the “pressure downstream of the throttle” is a pressure downstream of the throttle valve.

  (2) It is preferable that the supercharging pressure control means increases the supercharging pressure as the acceleration request increases, and the throttle control means decreases the throttle opening as the acceleration request increases. Is preferred. In other words, it is preferable to decrease the supercharging pressure and increase the throttle opening as the acceleration request is smaller.

(3) It is preferable to provide estimation means for estimating the usage frequency of the brake booster. In this case, it is preferable that the calculation unit calculates the negative pressure target value based on the use frequency estimated by the estimation unit.
The above “usage frequency” is an “estimated frequency” corresponding to a usage state of the brake booster in the future from that time point. For example, the brake booster is used within a predetermined time from that time point. It means the size of possibility.

  The above “frequency of use” includes, for example, the time until the brake booster is used next time, the amount of use estimated to be used next time by the brake booster (the brake booster is used next time, etc.) It is preferable that information on the amount of master back negative pressure to be stored by the time it is stored is included. This information is estimated based on, for example, the number and frequency of actual use of the brake booster (number of times per unit time), actual usage (amount of master back negative pressure consumed by the brake booster), etc. can do.

  (4) It is preferable that the estimation means estimates the use frequency based on an accelerator opening change rate (that is, an amount of change of the accelerator opening per unit time). For example, it is preferable that the estimation means estimate that the greater the accelerator opening change rate, the lower the possibility that the brake operation will be performed later, and the lower the frequency of use of the brake booster. In this case, it is preferable that the calculation means increases the negative pressure target value as the use frequency of the brake booster is lower. That is, it is preferable to increase the recovery time of the master back negative pressure by increasing the negative pressure target value as the accelerator opening change rate is larger.

  On the other hand, it is preferable that the estimation means estimates that the use frequency of the brake booster increases as the accelerator opening change rate decreases. In this case, it is preferable that the calculation means decrease the negative pressure target value as the use frequency of the brake booster increases. In other words, it is preferable that the negative pressure target value is decreased and the master back negative pressure is quickly recovered as the accelerator opening change rate is smaller.

  (5) It is preferable that the said estimation means estimates the said usage frequency based on a road surface gradient. For example, it is preferable that the estimation means estimate that when the road surface gradient is flat or ascending, there is a low possibility that a brake operation will be performed thereafter, and the use frequency of the brake booster is reduced. On the other hand, when the road surface gradient is a downhill, it is preferable to estimate that there is a high possibility that the brake operation will be performed thereafter, and that the frequency of use of the brake booster is increased.

That is, when the road surface gradient is flat or uphill, the master back negative pressure is gradually recovered, and when the road surface gradient is a down slope, the master back negative pressure is recovered quickly. Is preferred.
In addition, when the road surface gradient is an uphill gradient, it is preferable to estimate that the use frequency decreases as the absolute value of the gradient increases. On the other hand, when the road surface gradient is a downward gradient, it is preferable to estimate that the use frequency increases as the absolute value of the gradient increases.

  (6) It is preferable that the estimation means estimates the use frequency based on the number of depressions or the depression amount of the brake pedal. For example, it is preferable that the estimation means estimate that the more frequently the brake pedal is depressed during a predetermined time, the more frequently the brake booster is used. Alternatively, it is preferable to estimate that the use frequency of the brake booster increases as the amount of decrease in the internal pressure of the brake booster within a predetermined time increases.

(7) Moreover, when the master back negative pressure of the said brake booster is less than the threshold set based on the use condition of the said brake booster, the determination means which determines with the said master back negative pressure being insufficient is provided. Is preferred.
Here, the “use state of the brake booster” means a use state of the brake booster in the past from that point. Therefore, it is preferable to set the threshold value using a parameter representing a record of actual use of the brake booster within a predetermined time until that time. For example, the threshold value may be set based on the accelerator opening change rate, the road surface gradient, the number of depressions of the brake pedal, the depression amount, and the like.

  According to the disclosed engine control device, the supercharging pressure and the negative pressure downstream of the throttle due to the change in the supercharging pressure are offset by the intake system pressure due to the change in the throttle opening, By controlling the throttle opening, the acceleration can be improved while recovering the master back negative pressure. Therefore, it is possible to achieve both braking performance and acceleration performance under a situation where the master back negative pressure is insufficient.

It is a figure which illustrates the structure of the engine which concerns on one Embodiment. It is a figure which illustrates the hardware constitutions of an engine control apparatus. It is a figure which illustrates the block configuration of an engine control apparatus. It is an example of the control map regarding the correction of the negative pressure target value in the engine control device, (a) is based on the accelerator opening change rate, (b) is based on the brake operation, (c) is based on the road surface gradient. is there. It is an example of the control map regarding the setting of the waste gate opening degree in an engine control apparatus. It is a flowchart which illustrates the control procedure in an engine control apparatus. It is a flowchart which illustrates the control procedure in an engine control apparatus. It is a time chart for demonstrating the control effect | action at the time of slow acceleration by an engine control apparatus, (a) is an accelerator operation amount, (b) is a brake operation amount, (c) is a throttle opening degree, (d) is a waste gate. The opening degree, (e) indicates the master back negative pressure and the intake manifold pressure. In addition, (f) shows the master back negative pressure and intake manifold pressure as a comparative example. It is a time chart for demonstrating the control effect | action at the time of rapid acceleration by an engine control apparatus, (a) is an accelerator operation amount, (b) is a brake operation amount, (c) is a throttle opening degree, (d) is a waste gate. The opening degree, (e) indicates the master back negative pressure and the intake manifold pressure. It is a time chart for demonstrating the control effect | action when the brake frequency by an engine control apparatus is high, (a) shows throttle opening, (b) shows intake manifold pressure, (c) shows master back negative pressure.

  An engine control apparatus as an embodiment will be described with reference to the drawings. Note that the embodiment described below is merely an example, and there is no intention to exclude various modifications and technical applications that are not explicitly described in the following embodiment. Each configuration of the present embodiment can be implemented with various modifications without departing from the spirit of the present embodiment, and can be selected or combined as necessary.

[1. Device configuration]
[1-1. engine]
The engine control device of the present embodiment is applied to the on-vehicle gasoline engine 10 (hereinafter simply referred to as the engine 10) shown in FIG. The engine 10 includes a supercharging system using an exhaust pressure and an EGR system (Exhaust Gas Recirculation). FIG. 1 shows one of a plurality of cylinders (cylinders) provided in a multi-cylinder engine 10. A piston is slidably mounted in the cylinder, and the reciprocating motion of the piston is converted into rotational motion of the crankshaft via a connecting rod (connecting rod).

  An intake port and an exhaust port are provided on the top surface of each cylinder, and an intake valve and an exhaust valve are provided in each port opening. In addition, a spark plug 15 is provided between the intake port and the exhaust port in a state where the tip thereof protrudes toward the combustion chamber. The timing of ignition at the spark plug 15 (ignition timing) is controlled by the engine control device 1.

  The engine 10 is provided with an in-cylinder injection valve 11 and a port injection valve 12 as injectors for supplying fuel to each cylinder. The in-cylinder injection valve 11 is a direct injection injector that directly injects fuel into the cylinder, and the port injection valve 12 is an injector that injects fuel into the intake port. The fuel injection amount injected from these injection valves 11 and 12 and the injection timing thereof are controlled by the engine control device 1. For example, a control pulse signal is transmitted from the engine control device 1 to the injection valves 11 and 12, and the injection holes of the injection valves 11 and 12 are opened only during a period corresponding to the magnitude of the control pulse signal. Accordingly, the fuel injection amount becomes an amount corresponding to the magnitude (drive pulse width) of the control pulse signal, and the injection timing corresponds to the time when the control pulse signal is transmitted.

[1-2. Intake and exhaust system]
The upper part of the intake valve is connected to an intake variable valve mechanism 28 for changing the valve lift amount and valve timing, and the upper part of the exhaust valve is connected to an exhaust variable valve mechanism 29. The operations of the intake valve and the exhaust valve are controlled by the engine control device 1 described later via these variable valve mechanisms 28 and 29. Each of the variable valve mechanisms 28 and 29 includes, for example, a variable valve lift mechanism and a variable valve timing mechanism as a mechanism for changing the rocking amount and rocking timing of the rocker arm.

  The variable valve lift mechanism is a mechanism that continuously changes the valve lift amount of each of the intake valve and the exhaust valve. This variable valve lift mechanism has a function of changing the magnitude of swing (valve lift amount) transmitted from the cam fixed to the camshaft to the rocker arm or tappet. The variable valve timing mechanism is a mechanism for changing the opening / closing timing (valve timing) of each of the intake valve and the exhaust valve. This variable valve timing mechanism has a function of changing the rotational phase of the cam or camshaft that causes the rocker arm to swing.

  The intake system 20 and the exhaust system 30 of the engine 10 are provided with a turbocharger 16 (supercharger) that performs supercharging with exhaust pressure. The turbocharger 16 is interposed across both the intake passage 21 connected to the upstream side of the intake port and the exhaust passage 31 connected to the downstream side of the exhaust port. The turbine 16A (supercharging turbine) of the turbocharger 16 is rotated by the exhaust pressure in the exhaust passage 31 and transmits the rotational force to the compressor 16B on the intake passage 21 side. In response to this, the compressor 16B feeds the air in the intake passage 21 while compressing it to the downstream side, and supercharges each cylinder. The supercharging operation of the turbocharger 16 is controlled by the engine control device 1.

  An intercooler 25 is provided on the intake passage 21 downstream of the compressor 16B to cool the compressed air. Further, an air filter 22 is provided on the upstream side of the compressor 16B, and air taken in from the outside is filtered. Further, a bypass passage 23 is provided so as to connect the upstream and downstream intake passages 21 of the compressor 16 </ b> B, and a bypass valve 24 is interposed on the bypass passage 23. The amount of air flowing through the bypass passage 23 is adjusted according to the opening degree of the bypass valve 24. The bypass valve 24 is controlled, for example, in the opening direction when the vehicle is suddenly decelerated, and functions to release the supercharging pressure supplied from the compressor 16B to the upstream side again. The opening degree of the bypass valve 24 is controlled by the engine control device 1.

  An EGR passage 34 is provided between the downstream side of the compressor 16B in the intake system 20 and the upstream side of the turbine 16A in the exhaust system 30. The EGR passage 34 is a passage that guides exhaust gas that has just been exhausted from the cylinder to the upstream side of the cylinder again. The EGR passage 34 is provided with an EGR cooler 35 for cooling the reflux gas. Cooling the reflux gas lowers the combustion temperature in the cylinder and reduces the generation rate of nitrogen oxides. Further, an EGR valve 36 for adjusting the recirculation amount of the exhaust gas is interposed at the junction between the EGR passage 34 and the intake system 20. The valve opening degree of the EGR valve 36 is variable and is controlled by the engine control device 1.

  A throttle body is connected to the downstream side of the intercooler 25, and an intake manifold (intake manifold) is connected to the downstream side thereof. The throttle body is disposed on the upstream side of the junction between the EGR passage 34 and the intake system 20 described above. An electronically controlled throttle valve 26 is provided inside the throttle body. The amount of air flowing toward the intake manifold is adjusted according to the opening of the throttle valve 26 (throttle opening TH). The throttle opening TH is controlled by the engine control device 1.

  The intake manifold (intake manifold) is provided with a surge tank 27 for temporarily storing air flowing to each cylinder. The junction between the aforementioned EGR passage 34 and the intake system 20 is located upstream of the surge tank 27. Therefore, outside air and exhaust gas can be mixed in the surge tank 27. The intake manifold downstream of the surge tank 27 is formed so as to branch toward the intake port of each cylinder, and the surge tank 27 is located at the branch point. The surge tank 27 functions to alleviate intake pulsation and intake interference that can occur in each cylinder.

  A catalyst device 33 is interposed on the exhaust passage 31 downstream of the turbine 16A. This catalyst device 33 purifies, decomposes, and removes components such as PM (Particulate Matter), nitrogen oxide (NOx), carbon monoxide (CO), and hydrocarbon (HC) contained in the exhaust gas, for example. It has a function to do. Further, an exhaust manifold (exhaust manifold) branched toward the exhaust port of each cylinder is connected to the upstream side of the turbine 16A.

  A bypass 32 is provided so as to connect the upstream and downstream exhaust passages 31 of the turbine 16 </ b> A, and an electronically controlled waste gate valve 17 is interposed on the bypass 32. The waste gate valve 17 is a supercharging pressure adjusting valve for controlling the exhaust flow rate flowing into the turbine 16A side to change the supercharging pressure. The waste gate valve 17 is provided with a waste gate actuator 18 to electrically control the position (that is, the opening) of the valve body. The opening degree of the waste gate valve 17 (the waste gate opening degree D) is controlled by the engine control device 1.

[1-3. Brake system]
The brake pedal 44 is provided with a negative pressure (vacuum) braking booster 40. The brake booster 40 includes a master back 43 (brake booster) for assisting the driver to depress the brake, and a master cylinder 45 that generates brake hydraulic pressure. The interior of the master back 43 is divided into two chambers by a power piston (not shown), and the pressure (negative pressure) in the intake manifold is introduced into one chamber. Also, the other room has a structure in which atmospheric pressure is introduced simultaneously with the brake depression operation.

A negative pressure passage 41 connects between one room of the master back 43 and the intake system 20. The connection position of the negative pressure passage 41 and the intake system 20 is on the downstream side of the throttle valve 26, for example, the position of the surge tank 27. The negative pressure passage 41 is provided with a check valve 42 that allows pressure relief from the master back 43 side to the intake system 20 side and prevents pressure relief in the reverse direction. Thus, when the pressure on the master back 43 side is lower than the pressure on the intake system 20 side, air does not flow from the intake system 20 side to the master back 43 side. Hereinafter, the pressure in one chamber of the master back 43 (master back pressure) is also referred to as “master back negative pressure P _VAC ”.

  A piston that moves in conjunction with the brake pedal 44 is inserted into the master cylinder 45, and brake fluid is sealed in a chamber on one side defined by the piston. The pedal force input to the brake pedal 44 is urged in the stepping direction by the master back 43 and is converted into a brake fluid pressure via a piston in the master cylinder 45. The brake hydraulic pressure generated here is transmitted to various braking devices via a brake hydraulic circuit (not shown).

[1-4. Sensor system]
An accelerator opening sensor 51 that detects the amount of depression of the accelerator pedal 47 (accelerator opening APS) is provided at an arbitrary position of the vehicle. The accelerator opening APS is a parameter corresponding to the driver's acceleration request and intention to start, in other words, a parameter correlated to the load of the engine 10 (output request to the engine 10).

An air flow sensor 52 for detecting the intake flow rate Q _IN is provided in the intake passage 21. The intake air flow rate Q _IN is a parameter corresponding to the flow rate of air that has passed through the air filter 22. An intake manifold pressure sensor 53 and an intake air temperature sensor 54 are provided in the surge tank 27. Intake manifold pressure sensor 53 detects the pressure in the surge tank 27 as the intake manifold pressure P _IM, the intake air temperature sensor 54 for detecting an intake air temperature T _IM in the surge tank 27.

In the vicinity of the crankshaft, an engine speed sensor 55 that detects the engine speed Ne (the number of revolutions per unit time) is provided. A cooling water temperature sensor 56 for detecting the temperature of the engine cooling water (cooling water temperature W _T ) is provided at an arbitrary position on the cooling water circulation path of the engine 10.

  The waste gate actuator 18 is provided with a hall sensor 57 that detects the stroke of the valve body driving member corresponding to the waste gate opening degree D. The stroke detected by the hall sensor 57 corresponds to the amount of movement of the valve body drive member from the reference position. Further, a linear air-fuel ratio sensor 58 and an oxygen concentration sensor 59 are arranged inside the catalyst device 33. The linear air-fuel ratio sensor 58 detects the air-fuel ratio of the exhaust gas flowing into the catalyst device 33, and the oxygen concentration sensor 59 detects the oxygen concentration of the exhaust gas flowing out from the catalyst device 33.

The master back 43 is provided with a negative pressure sensor 60 that detects the master back negative pressure P _VAC . On the other hand, the master cylinder 45 is provided with a brake fluid pressure sensor 61 that detects the brake fluid pressure BRK. The master back negative pressure P _VAC and brake fluid pressure BRK information shows the number of times the master back 43 is actually used, the number of brakes, the amount of master back negative pressure P _VAC consumed by depressing the brake pedal 44, etc. Used to do.

Also, at any position within or vehicle engine control device 1, an atmospheric pressure sensor 62 for detecting the atmospheric pressure P _BP, road surface gradient sensor 63 which detects a road surface gradient INC is provided. Information on the atmospheric pressure P _BP and the road gradient INC is used to grasp the traveling environment of the vehicle. Various information detected by the various sensors 51 to 63 is transmitted to the engine control apparatus 1.

[1-5. Control system]
A vehicle equipped with the engine 10 is provided with an engine control device 1 (Engine Electronic Control Unit). The engine control device 1 is configured as an electronic device in which a microprocessor such as a CPU (Central Processing Unit) and an MPU (Micro Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like are integrated. Is connected to a communication line of an in-vehicle network provided in the network. Note that various known electronic control devices such as a brake control device, a transmission control device, a vehicle stability control device, an air conditioning control device, and an electrical component control device are communicably connected to each other on the in-vehicle network. An electronic control device other than the engine control device 1 is called an external control system, and a device controlled by the external control system is called an external load device.

The engine control device 1 is an electronic control device that comprehensively controls a wide range of systems such as an ignition system, a fuel system, an intake / exhaust system, and a valve system related to the engine 10, and air supplied to each cylinder of the engine 10. It controls the amount, fuel injection amount, ignition timing of each cylinder, supercharging pressure, etc. The aforementioned various sensors 51 to 63 are connected to the input port of the engine control device 1. Specific input information includes accelerator opening APS, intake air flow rate Q _IN , intake manifold pressure P _IM , intake air temperature T _IM , engine speed Ne, cooling water temperature W _T , stroke of waste gate actuator 18 (waste gate opening D ), Exhaust air-fuel ratio, oxygen concentration, master back negative pressure P _VAC , brake fluid pressure BRK, atmospheric pressure P _BP , road gradient INC, and the like.

Specific control objects of the engine control device 1 include the fuel injection amount and the injection timing injected from the in-cylinder injection valve 11 and the port injection valve 12, the ignition timing by the ignition plug 15, and the valve lifts of the intake valve and the exhaust valve. Examples include the amount and valve timing, the operating state of the turbocharger 16, the throttle opening TH, the opening of the bypass valve 24, the waste gate opening D, and the like.
In the present embodiment, the relationship between the master back negative pressure P _VAC and the opening _amounts of the waste gate valve 17 and the throttle valve 26 will be described in detail.

[2. Overview of control]
[2-1. Determination of master back negative pressure]
The engine control device 1 performs control to limit the operations of the waste gate valve 17 and the throttle valve 26 in accordance with the operating state of the braking booster 40 in order to ensure the braking performance of the vehicle. Here, it is ensured that the state where the master back negative pressure P _VAC is less than the predetermined threshold P _{VAC_TH} is secured and maintained, or the increased master back negative pressure P _VAC is quickly recovered to less than the predetermined threshold P _{VAC_TH.} In addition, each of the waste gate opening D and the throttle opening TH is controlled. The predetermined threshold value P _{VAC_TH} is set to a value that is at least less than the standard atmospheric pressure, and a value (for example, 800 to 900 [hPa) at which the braking assist force applied when the brake pedal 44 is depressed is greater than or equal to a desired magnitude. ] The following values are set.

The threshold value P _{VAC_TH} may be given as a fixed value that is set in advance, but in the present embodiment, it is given as a variable value that varies depending on the driving conditions of the vehicle. Specifically, the threshold value P _{VAC_TH} is given as a function of the atmospheric pressure P _BP , the road surface gradient INC, the accelerator opening change rate ΔAPS, and the brake frequency. For example, when the actually measured atmospheric pressure P _BP is lower than the standard atmospheric pressure, the value of the threshold value P _{VAC_TH} is set small according to the degree of pressure decrease. This ensures a differential pressure acting on one side and the other side of the power piston built in the master back 43 regardless of the traveling environment of the vehicle and the height of the altitude, thereby ensuring the braking assist force.

Further, the road surface gradient INC, the accelerator opening change rate ΔAPS, and the brake frequency are index values representing the use state of the master back 43, respectively. Based on these index values, the magnitude of the braking assist force that should be stored as a preparation for the subsequent braking operation is determined, and the threshold value P _{VAC_TH} is decreased when the braking assist force is to be increased. ) Is set. However, if the threshold P _{VAC_TH} is set to a small value, the master back negative pressure P _VAC is less likely to be less than the threshold P _{VAC_TH} instead of increasing the braking assist force. Therefore, as the setting of the threshold value P _{VAC_TH} according to the use state of the master back 43, the setting for preferentially securing the magnitude of the braking assist force and the number of times the braking assist force is applied are preferentially secured. The setting for this is considered.

Based on the former setting, when the road surface gradient INC is a downward gradient, it is conceivable that the threshold value P _{VAC_TH} is set to be small so that the braking assist force is increased as compared to when traveling on a flat road. On the other hand, based on the latter setting, when the road surface gradient INC is a downward slope, the threshold P _{VAC_TH} may be set to a larger value in order to maintain the number of braking assists than when traveling on a flat road. . The relationship between the accelerator opening change rate ΔAPS and the threshold value P _{VAC_TH} can also be set in two ways. The relationship between the brake frequency and the threshold value P _{VAC_TH} is the same, and can be set in two ways.

[2-2. Wastegate opening and throttle opening control]
The waste gate opening D and the throttle opening TH are basically controlled according to the output required for the engine 10. For example, a driver's acceleration request or a request from an external load device is input to the engine control device 1, and a target torque of the engine 10 is set according to these requests. In addition, the intake air amount corresponding to the target torque is calculated, the supercharging amount is calculated, the waste gate opening D is controlled according to the supercharging amount, and the throttle opening TH is controlled according to the intake air amount. The Such control is performed when the master back negative pressure P _VAC is less than the threshold value P _{VAC_TH} (that is, when the negative pressure for braking is not insufficient).

On the other hand, when the master back negative pressure P _VAC becomes _{equal to} or higher than the threshold value P _{VAC_TH} , the engine control device 1 restricts the operations of the waste gate valve 17 and the throttle valve 26 to reduce the intake manifold pressure P _IM and the master back negative pressure P _VAC. Add. That is, the boost pressure is controlled wastegate opening D so as not to be excessively large, so that the intake manifold pressure P _IM is equal to or less than a predetermined negative pressure target value P _{VAC_LIM,} controls the throttle valve 26. For example, even if the throttle opening TH for obtaining the intake air amount corresponding to the target torque is fully open, the throttle opening TH is reduced if the master back negative pressure P _VAC is equal to or greater than the threshold value P _{VAC_TH} . That is, in the state where the master back negative pressure P _VAC is insufficient, the operation for opening the throttle opening TH is restricted.

However, in a state where the supercharging pressure is low and the throttle opening TH is throttled, the acceleration performance when the master back negative pressure P _VAC recovers again below the threshold P _{VAC_TH} is greatly reduced. Therefore, while maintaining the balance of intake manifold pressure P _IM is equal to or less than a predetermined negative pressure target value P _{VAC_LIM,} it implements the control to reduce the throttle opening TH with increasing boost pressure in accordance with the magnitude of the acceleration request. For example, when the acceleration request is large, the supercharging pressure is slightly increased and the throttle opening TH is decreased so that the increased pressure is offset. Thus, while the supercharging pressure is increased, limiting the intake manifold pressure P _IM below a predetermined negative pressure target value P _{VAC_LIM.}

The negative pressure target value P _{VAC_LIM} is set in accordance with the frequency of use of the master back 43 within a range less than the aforementioned threshold value P _{VAC_TH} . Here, “the usage frequency of the master back 43” means “the number of times, the frequency, the size of the prospect that the master back 43 will be used from now on”, and the like. That is, the “usage frequency of the master back 43” here is an “estimated frequency” corresponding to the use state of the master back 43 in the future from that time point. For example, the master back 43 within a predetermined time from that time point. 43 corresponds to an “expected value” indicating the magnitude of the possibility of being used.

When intake manifold pressure P _IM is controlled to a negative pressure target value P _{VAC_LIM,} introduces a negative pressure from the surge tank 27 to the master back 43 (i.e., missing the pressure from the master back 43 side to the surge tank 27 side), Masterback negative pressure P _VAC decreases. At this time, the rate of decrease in the master back negative pressure P _VAC becomes a speed corresponding to the pressure difference between the master back negative pressure P _VAC and intake manifold pressure P _IM, reduction of the master back negative pressure P _VAC lower the intake manifold pressure P _IM Increases speed. Therefore, by controlling the negative pressure target value P _{VAC_LIM} , the rate of decrease of the master back negative pressure P _VAC (that is, the recovery speed of the master back negative pressure P _VAC ) can be adjusted.

In the present embodiment, when there is a high possibility that the braking assist force will be required again (frequency of use of the master back 43), control for increasing the recovery speed of the master back negative pressure P _VAC is performed. For example, when the accelerator opening change rate ΔAPS is relatively small, it is determined that the driver's acceleration request is not so large and the brake pedal 44 is likely to be depressed again, and the negative pressure target value P _{VAC_LIM} is Small (low pressure side) is set. That is, when there is a high possibility that the brake pedal 44 is depressed, the throttle opening TH is controlled so that the _masterback negative pressure P _VAC is quickly recovered. On the other hand, when the accelerator opening change rate ΔAPS is relatively large, it is determined that there is a low possibility that the brake operation will be performed immediately after that, and the negative pressure target value P _{VAC_LIM} is set large (to the high pressure side). In this case, the master back negative pressure P _VAC recovers slowly without difficulty.

Further, as parameters for determining the use frequency of the master back 43, the road surface gradient INC, the number of depressions of the brake pedal 44, the depression amount, and the like are referred to. For example, if the road surface gradient INC is a downward gradient, it is determined that the brake pedal 44 is more likely to be depressed again than when traveling on a flat road, and the negative pressure target value P _{VAC_LIM} is set smaller. On the other hand, if the road surface gradient INC is an upward gradient, it is determined that the possibility that the brake pedal 44 is depressed is low, and the negative pressure target value P _{VAC_LIM} is set to be large. Similarly, when the number of depressions and the depression amount of the brake pedal 44 per unit time are large, the negative pressure target value P _{VAC_LIM} is set small in preparation for the next depression of the brake pedal 44. On the other hand, when the number of depressions and the depression amount of the brake pedal 44 are small, the negative pressure target value P _{VAC_LIM} is set large.

[3. Configuration of control device]
A hardware configuration of the engine control apparatus 1 is illustrated in FIG. The engine control device 1 includes a central processing unit 71, a main storage device 72, an auxiliary storage device 73, and an interface device 74, and these are communicably connected via an internal bus 75. Further, each of these devices 71 to 74 operates by receiving power supplied from a power source (not shown) (for example, an in-vehicle battery or a button battery).

  The central processing unit 71 is a processing unit (processor) incorporating a control unit (control circuit), an arithmetic unit (arithmetic circuit), a cache memory (register group), and the like. Further, the main storage device 72 is a memory device that stores programs and working data, and includes, for example, the aforementioned RAM and ROM. On the other hand, the auxiliary storage device 73 is a memory device that stores data and programs that are held for a longer period of time than the main storage device 72. This includes storage devices such as solid state drives (SSD). The interface device 74 controls input / output (I / O) between the engine control device 1 and the outside. For example, information is exchanged between the various sensors 51 to 63 mounted on the vehicle and the external control system and the engine control device 1 via the interface device 74.

  FIG. 3 is a block diagram for explaining the processing content executed by the engine control apparatus 1. These processing contents are recorded on the auxiliary storage device 73 or a removable medium as an application program, for example. Further, when the program is executed, the contents of the program are expanded in the memory space in the main storage device 72 and executed by the central processing unit 71. When the processing contents are functionally classified, the program includes a negative pressure determination unit 2, a negative pressure target value calculation unit 3, an acceleration request calculation unit 4, a waste gate control unit 5, and a throttle control unit 6. Each of these elements may be realized by an electronic circuit (hardware), or a part of these functions may be provided as hardware and the other part may be software.

[3-1. Negative pressure determination unit]
The negative pressure determination unit 2 (determination means) determines _whether the master back negative pressure P _VAC is excessive or insufficient. The negative pressure determination unit 2 includes a threshold setting unit 2a and a negative pressure shortage determination unit 2b.
The threshold setting unit 2 a sets the above-described threshold P _{VAC_TH} based on the usage state of the master back 43. Here, the atmospheric pressure P _BP , the road surface gradient INC, the accelerator opening change rate ΔAPS, the brake frequency, and the like are referred to as the use state of the master back 43. For example, the lower the atmospheric pressure P _BP, set threshold P _{VAC_TH} is small (on the low-pressure side), the threshold value P _{VAC_TH} higher atmospheric pressure P _BP is set larger. However, the threshold P _{VAC_TH} is not set to a value equal to or higher than the atmospheric pressure P _BP . Further, the threshold value P _{VAC_TH} is corrected according to the road surface gradient INC, the accelerator opening change rate ΔAPS, and the brake frequency. Information on the threshold value P _{VAC_TH} set here is transmitted to the negative pressure _deficiency determination unit 2b.

In the _setting where the threshold value P _{VAC_TH} is decreased when the road surface gradient INC is a downward gradient and the threshold value P _{VAC_TH} is increased when the road surface gradient INC is an upward gradient, the braking assist force increases with respect to the acceleration of the vehicle body due to gravity. On the other hand, if the threshold value P _{VAC_TH} is increased when the road surface gradient INC is downward and the threshold value P _{VAC_TH} is decreased when the road surface gradient INC is upward, the number of braking assists on downhill roads increases and braking performance is ensured. The

In a setting where the threshold P _{VAC_TH} is decreased when the accelerator opening change rate ΔAPS is large and the threshold P _{VAC_TH} is increased when the accelerator opening change rate ΔAPS is small, braking during sudden braking that can be performed after the accelerator operation is performed. Assist force increases. On the other hand, in a setting where the threshold P _{VAC_TH} is increased when the accelerator opening change rate ΔAPS is large and the threshold P _{VAC_TH} is decreased when the accelerator opening change rate ΔAPS is small, braking is performed as the vehicle momentum increases. The number of assists increases and braking performance is ensured.

In addition, when the brake frequency is high (when the number of times the brake is depressed per unit time is high), the threshold P _{VAC_TH} is reduced, and when the brake frequency is low, the threshold P _{VAC_TH} is increased. Even if the power decreases, the braking assist force increases, so that it is easy to obtain a desired braking force. On the other hand, if the threshold P _{VAC_TH} is increased when the brake frequency is high and the threshold P _{VAC_TH} is decreased when the brake frequency is low, for example, the number of braking assists on a hairpin curve road that requires frequent braking operations increases. And brake performance is ensured.

Condition negative shortage determination unit 2b, the magnitude relationship between the threshold set P _{VAC_TH} master back negative pressure P _VAC and a threshold setting unit 2a detected by the negative pressure sensor 60, the master back negative pressure P _VAC is insufficient It is determined whether or not. Here, when the master back negative pressure P _VAC is _{equal to} or higher than the threshold P _{VAC_TH} (when the master back negative pressure P _VAC is _higher than the threshold P _{VAC_TH} , ie, the negative pressure is _less than the threshold P _{VAC_TH} ), the master back It is determined that the negative pressure P _VAC is insufficient. On the other hand, when the master back negative pressure P _VAC is less than the threshold P _{VAC_TH} , it is determined that the master back negative pressure P _VAC is sufficient. The determination result here is transmitted to the negative pressure target value calculation unit 3, the acceleration request calculation unit 4, the waste gate control unit 5, and the throttle control unit 6.

[3-2. Negative pressure target value calculation unit]
Negative pressure target value calculating unit 3 is designed to calculate the limit value of the intake manifold pressure P _IM to target (negative pressure target value P _{VAC_LIM).} Here, an accelerator correction unit 3a, a brake correction unit 3b, a road surface gradient correction unit 3c, and a totaling unit 3d are provided. The three types of correction units 3 a to 3 c function as estimation means for estimating the usage frequency of the master back 43. The counting unit 3d functions as a calculation unit that calculates the negative pressure target value P _{VAC_LIM} downstream of the throttle in the intake system 20 based on the usage frequency.

The accelerator correction unit 3a estimates the usage frequency of the master back 43 based on the accelerator opening change rate _ΔAPS and calculates the correction amount ΔP _{VAC_APS} . This correction amount ΔP _{VAC_APS} is for _reflecting the estimated use frequency of the master back 43 in the negative pressure target value P _{VAC_LIM} . The accelerator correction unit 3a records and stores a map, a mathematical expression, and the like that define the relationship between the accelerator opening change rate ΔAPS and the correction amount ΔP _{VAC_APS} . For example, as shown in FIG. 4A, a map is prepared in which the correction amount ΔP _{VAC_APS} increases as the accelerator opening change rate ΔAPS increases. This setting is based on the idea that “the greater the accelerator opening change rate ΔAPS is, the less likely the brake operation is to be performed immediately after that”. Information of the correction amount ΔP _{VAC_APS} calculated here is transmitted to the totaling unit 3d.

The brake correction unit 3b estimates the usage frequency of the master back 43 based on the brake fluid pressure BRK and calculates the correction amount ΔP _{VAC_BRK} . This correction amount ΔP _{VAC_BRK} is for _reflecting the estimated use frequency of the master back 43 in the negative pressure target value P _{VAC_LIM} . In the brake correction unit 3b, the depression frequency and the depression operation amount of the brake pedal 44 are calculated from the change in the brake fluid pressure BRK, and the correction amount ΔP _{VAC_BRK} is calculated based on the depression frequency and the depression operation amount. For this reason, the brake correction unit 3b records and stores maps, mathematical expressions, and the like that define the relationship between the depression frequency, the depression operation amount, and the correction amount ΔP _{VAC_BRK} .

For example, as shown in FIG. 4B, a map is prepared so that the correction amount ΔP _{VAC_BRK} increases as the depression frequency of the brake pedal 44 is lower or the depression operation amount is smaller. This setting is based on the idea that “the lower the frequency of depression of the brake pedal 44 or the smaller the amount of depression, the lower the possibility that the brake operation will be performed immediately after that”. The information of the correction amount ΔP _{VAC_BRK} calculated here is transmitted to the totaling unit 3d.

The road surface gradient correction unit 3c estimates the usage frequency of the master back 43 based on the road surface gradient INC and calculates a correction amount ΔP _{VAC_INC} . This correction amount ΔP _{VAC_INC is} also for _reflecting the estimated use frequency of the master back 43 in the negative pressure target value P _{VAC_LIM} . The road surface gradient correction unit 3c records and stores a map, a mathematical expression, and the like that define the relationship between the road surface gradient INC and the correction amount ΔP _{VAC_INC} . For example, as shown in FIG. _4C, a map is prepared so that the correction amount ΔP _{VAC_INC} increases as the road surface gradient INC increases (as the ascending gradient increases). This setting is based on the idea that “the greater the road gradient INC, the less likely the brake operation will be performed immediately after that”. The information of the correction amount ΔP _{VAC_INC} calculated here is transmitted to the counting unit 3d.

The totaling unit 3d calculates the negative pressure target value P _{VAC_LIM} using the three types of correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , ΔP _{VAC_INC} calculated by the correction units 3a to 3c. For example, a value obtained by subtracting the respective correction amounts from a preset standard limit value P _{VAC_LIM_BASE} is calculated, and the smallest value (the most restrictive value) is calculated as the final negative pressure target value P _{VAC_LIM} . Alternatively, the average value of the three types of correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , and ΔP _{VAC_INC} is calculated, and the value _obtained by subtracting the average value from the standard limit value P _{VAC_LIM_BASE} is calculated as the final negative pressure target value P _{VAC_LIM.} Good. The standard limit value P _{VAC_LIM_BASE} may be a fixed value set in advance, or may be a variable value set according to the engine speed Ne, the target torque of the engine 10, or the like. The final negative pressure target value P _{VAC_LIM} calculated here is transmitted to the throttle control unit 6.

[3-3. Acceleration request calculator]
The acceleration request calculator 4 (acceleration request calculator) calculates the magnitude of the acceleration request required for the engine 10. The acceleration request is an output request required for the engine from a vehicle driver or an external load device, and is accompanied by acceleration of the vehicle. Typically, the magnitude of the acceleration request is determined based on the accelerator opening APS and the accelerator opening change rate ΔAPS. For example, it is determined that the acceleration request is greater than or equal to a predetermined required amount, because the accelerator opening APS is greater than or equal to a predetermined aperture, and the accelerator opening variation rate ΔAPS is greater than or equal to a predetermined variation rate.

  In addition, not only the accelerator opening APS but also the engine rotational speed Ne, the magnitude of the acceleration request based on the magnitude of the output (power) required for the engine may be determined. Alternatively, the magnitude of the acceleration request based on the magnitude of torque (requested torque, target torque, etc.) required for the engine may be determined.

  The acceleration request calculation unit 4 of the present embodiment records and stores a map, a mathematical expression, and the like that define the relationship between the accelerator opening change rate ΔAPS and the acceleration request value REQ. The acceleration request calculation unit 4 calculates an acceleration request value REQ corresponding to the accelerator opening change rate ΔAPS based on these maps, mathematical expressions, and the like. The acceleration request value REQ is calculated as a larger value as the accelerator opening change rate ΔAPS is larger. The acceleration request value REQ calculated here is transmitted to the waste gate control unit 5 and the throttle control unit 6.

[3-4. Wastegate control unit]
The waste gate control unit 5 (supercharging pressure control means) controls the waste gate opening degree D based on the operating state of the engine 10. When the negative pressure determination unit 2 does not determine that the master back negative pressure P _VAC is insufficient, the waste gate opening D is, for example, the engine rotational speed Ne, engine load, air amount, charging efficiency Ec (target charging efficiency, such as the actual charging efficiency), the supercharging pressure, the accelerator opening APS, is set based on the coolant temperature W _T, and the like. In the present embodiment, the waste gate opening degree D is calculated based on a three-dimensional map using the engine speed Ne and the charging efficiency Ec as arguments.

The charging efficiency Ec is obtained by normalizing the volume of air filled in the cylinder per unit combustion cycle (unit time) to the gas volume in the standard state and then dividing by the cylinder volume. In other words, the charging efficiency Ec represents the ratio of the mass of air filled in the cylinder to the mass of air occupying the cylinder under standard atmospheric conditions, and the air introduced into the cylinder per unit combustion cycle (unit time). It is a parameter corresponding to the quantity. Therefore, parameters correlating to the intake air amount such as the volume efficiency Ev, the intake flow rate Q _IN , the target torque, and the target engine output can be used instead of the charging efficiency Ec.

  The waste gate control unit 5 outputs a control signal corresponding to the waste gate opening degree D to the waste gate actuator 18. Upon receiving the control signal, the waste gate actuator 18 drives the valve body driving member with a stroke corresponding to the control signal. As a result, the actual opening degree of the waste gate valve 17 becomes the waste gate opening degree D.

On the other hand, when the negative pressure determination unit 2 determines that the master back negative pressure P _VAC is insufficient, the waste gate control unit 5 controls the waste gate opening D according to the acceleration request value REQ. . FIG. 5 illustrates a map in which the relationship between the acceleration request value REQ and the waste gate opening degree D is defined. On this map, when the acceleration request value REQ is less than the predetermined value REQ1, the waste gate opening D is set to fully open (100 [%]). As a result, the turbine 16A has the lowest rotational efficiency (exhaust gas easily passes through the bypass 32). Further, when the acceleration request value REQ is equal to or greater than the predetermined value REQ1, the waste gate opening degree D is set to decrease (throttle) as the acceleration request value REQ increases. That is, the setting is such that the supercharging pressure by the turbocharger 16 increases as the acceleration request increases.

  The supercharging pressure that is the pressure upstream of the throttle of the engine 10 has a magnitude corresponding to the waste gate opening degree D. Therefore, the waste gate control unit 5 of the present embodiment functions as a supercharging pressure control unit that controls the supercharging pressure of the engine 10 based on the acceleration request required for the engine 10.

[3-5. Throttle control unit]
The throttle control unit 6 (throttle control means) controls the throttle opening TH based on the operating state of the engine 10. When the negative pressure determination unit 2 determines that the master back negative pressure P _VAC is not insufficient, the throttle control unit 6 determines that the actual throttle opening TH is an opening corresponding to the target torque of the engine 10. The throttle opening TH is controlled so that

On the other hand, if the master back negative pressure P _VAC is determined that the state of insufficient so that the negative pressure target value P _{VAC_LIM} the intake manifold pressure P _IM is calculated by the negative pressure target value calculation unit 3, a throttle opening Control the degree TH. That is, in the state where the master back negative pressure P _VAC is insufficient, the upper limit value of the intake manifold pressure P _IM is limited to a negative pressure target value P _{VAC_LIM.} At this time, the throttle opening TH is increased so that the excess or deficiency of the negative pressure downstream of the throttle due to the change in the supercharging pressure associated with the control of the waste gate valve 17 is offset with the negative pressure target value P _{VAC_LIM} as a reference. Is controlled.

For example, when the waste gate opening D is fully open (100%), it is determined that there is no influence of the supercharging pressure, the throttle opening TH intake manifold pressure P _IM becomes a negative pressure target value P _{VAC_LIM} is calculated Is done. On the other hand, when the waste gate opening degree D is slightly narrower than fully opened, the throttle opening degree TH is controlled to be smaller than when the waste gate opening degree D is fully opened. At this time, the throttle size of the throttle opening TH is controlled so as to cancel the negative pressure downstream of the throttle that is increased by reducing the waste gate opening D. That is, as the negative pressure of the throttle downstream changes in intake manifold pressure P _IM is canceled by reducing only the throttle opening TH amount corresponding to the increase, the magnitude of the throttle opening TH is set.

  As described above, when the waste gate valve 17 is controlled and the negative pressure downstream of the throttle is insufficient (higher than the target pressure), the throttle opening TH is reduced to compensate for the shortage. Further, as a result of controlling the waste gate valve 17, if the negative pressure downstream of the throttle is excessive (lower than the target pressure), the throttle opening TH is controlled to be large so as to cancel out the surplus.

As shown in FIG. 3, the throttle control unit 6 includes a target flow rate calculation unit 6a, a pressure ratio calculation unit 6b, a flow velocity calculation unit 6c, a mass flow velocity calculation unit 6d, and a throttle area calculation unit 6e.
The target flow rate calculation unit 6a calculates the target flow rate Q as a target value of the intake air amount that passes through the throttle valve 26 per unit time based on the target torque of the engine 10. The target torque is calculated based on a driver request torque set from the engine rotational speed Ne and the accelerator opening APS, an external request torque required for the engine 10 from an external control system, and the like. Further, the target flow rate Q is calculated based on the target torque and the engine rotational speed Ne. At this time, the value of the target flow rate Q may be corrected based on the intake air temperature _TIM , the cooling water temperature W _T , the intake manifold pressure P _IM , the atmospheric pressure P _BP , the intake air density, and the like.

The pressure ratio calculation unit 6b calculates the pressure ratio between the upstream side and the downstream side of the throttle valve 26. Here, two types of pressure ratios are calculated: the actual pressure ratio and the pressure ratio at the time of restriction. Actual pressure ratio is the ratio between the upstream pressure P _THU of the intake manifold pressure P _IM and the throttle valve 26 actually found by the intake manifold pressure sensor 53 (or the atmospheric pressure P _BP). Pressure ratio calculating section 6b, for example a value is calculated by dividing the intake manifold pressure P _IM at atmospheric pressure P _BP as the actual pressure ratio. On the other hand, the time limit pressure ratio is an estimate of the pressure ratio in a state where the intake manifold pressure P _IM is limited to a negative pressure target value P _{VAC_LIM.} For example, the pressure ratio calculation unit 6b _obtains , as a pressure ratio at the time of restriction, a value obtained by _{dividing the} negative pressure target value P _{VAC_LIM} by the added value (P _BP + P _X ) of the atmospheric pressure P _BP and the pressure increase amount P _X due to supercharging. calculate. The pressure increase amount P _X due to supercharging is calculated based on the waste gate opening degree D. The smaller the waste gate opening D is, the larger the pressure increase amount P _X is. When the waste gate opening D is fully open (100 [%]), the value of the pressure increase amount P _X is 0.

The flow velocity calculation unit 6c calculates the intake throttle passage flow velocity corresponding to each case based on the two pressure ratios calculated by the pressure ratio calculation unit 6b. The flow velocity calculation unit 6c uses a map, a mathematical formula, or the like that defines the relationship between the pressure ratio and the amount of change in the flow velocity through the throttle, and the actual flow velocity U corresponding to the actual pressure ratio and the restriction time corresponding to the restriction pressure ratio. Calculate the flow velocity U _LIM . Also, one of the actual flow rate U and the limited flow rate U _LIM is calculated as the control flow rate U _CTL . For example, the control flow velocity U _CTL increases as the pressure ratio value decreases.

The mass flow velocity calculation unit 6d calculates a mass flow velocity M _MACH per unit area for the intake air passing through the throttle valve 26. The mass flow rate M _MACH is calculated based on the intake air temperature _TIM , the cooling water temperature W _T , the outside air temperature, the intake manifold pressure P _IM , the atmospheric pressure P _BP , the intake air density, and the like.
The throttle area calculation unit 6e calculates a target throttle opening area S corresponding to the throttle opening TH based on the target flow rate Q, the control flow velocity U _CTL , and the mass flow velocity M _MACH . The target throttle opening area S is obtained by dividing the target flow rate Q by a value obtained by multiplying the control flow velocity U _CTL by the mass flow velocity M _MACH . Further, the throttle control unit 6 outputs a control signal for matching the opening area of the throttle valve 26 with the target throttle opening area S, thereby controlling the throttle opening TH.

[4. flowchart]
FIG. 6 is a flowchart relating to the determination of the shortage of the master back negative pressure P _VAC and the setting of the negative pressure target value P _{VAC_LIM} , and FIG. 7 is a flowchart relating to the control of the waste gate opening D and the throttle opening TH. These flows are repeatedly executed in the engine control apparatus 1 at a predetermined calculation cycle.

[4-1. Master back negative pressure shortage determination]
In step A <b> 10, various information detected by the various sensors 51 to 63 is input to the engine control device 1. Here, accelerator opening APS, intake air flow rate Q _IN , intake manifold pressure P _IM , intake air temperature T _IM , engine speed Ne, cooling water temperature W _T , stroke of waste gate actuator 18 (waste gate opening D), exhaust air-fuel ratio , Oxygen concentration, master back negative pressure P _VAC , brake fluid pressure BRK, atmospheric pressure P _BP , road gradient INC, etc. are input. In Step A20, it is determined whether or not the number of ignitions is equal to or greater than a predetermined number from the time when the engine 10 is started. This determination is for ensuring rotational stability immediately after starting.

In Step A30, the threshold value setting unit 2a sets a threshold value P _{VAC_TH} related to the determination of the master back negative pressure P _VAC . In subsequent Step A40, the negative pressure _shortage determination unit 2b determines whether or not the master back negative pressure P _VAC is _{equal to} or higher than the threshold value P _{VAC_TH} . Here, if P _VAC ≧ P _{VAC_TH} is satisfied, it is determined that the master back negative pressure P _VAC is insufficient, and the process proceeds to step A50. On the other hand, if P _VAC <P _{VAC_TH} , since the master back negative pressure P _VAC is not insufficient, the process proceeds to step A100. In step A100, the value of the negative pressure target value P _{VAC_LIM} is set to the same value as the intake manifold pressure P _IM. As a result, the waste gate opening D and the throttle opening TH are not limited.

In Step A50, the standard limit value P _{VAC_LIM_BASE} is set in the counting unit 3d of the negative pressure target value calculation unit 3. The standard limit value P _{VAC_LIM_BASE} is set according to, for example, the engine rotational speed Ne or the target torque. In subsequent step A60, the accelerator correction unit 3a calculates a correction amount ΔP _{VAC_APS} based on the accelerator opening change rate ΔAPS. In Step A70, the brake correction unit 3b calculates a correction amount ΔP _{VAC_BRK} based on the depression frequency and the depression operation amount of the brake pedal 44. Similarly, in step A80, the road surface gradient correction unit 3c calculates the correction amount ΔP _{VAC_INC} based on the road surface gradient INC. For calculating these correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , ΔP _{VAC_INC} , for example, maps as shown in FIGS. 4A to 4C are used.

In step A90, the totaling unit 3d calculates three values _obtained by subtracting the correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , and ΔP _{VAC_INC} from the standard limit value P _{VAC_LIM_BASE} . Also, the smallest value between these three values and the standard limit value P _{VAC_LIM_BASE} is selected as the final negative pressure target value P _{VAC_LIM} . The value of the negative pressure target value P _{VAC_LIM} obtained here is set to a lower pressure as the accelerator opening change rate ΔAPS is smaller. Further, the lower the depression frequency of the brake pedal 44, the greater the depression amount, or the smaller the road surface gradient (the tighter the downward gradient), the lower the pressure is set. As the negative pressure target value P _{VAC_LIM} is lower, the restrictions on the waste gate opening D and the throttle opening TH are strengthened.

[4-2. Control of throttle opening]
In step B10, the engine control apparatus 1 calculates the target torque of the engine 10. The specific calculation method of the target torque is arbitrary, and is calculated based on, for example, the engine speed Ne, the accelerator opening APS, the operating state of the external load device, and the like.

  In step B20, the target flow rate calculation unit 6a calculates the target flow rate Q based on the target torque. Here, for example, based on the target torque, the target in-cylinder air amount to be introduced into the cylinder is calculated, and the target in-cylinder air amount subjected to predetermined intake advance calculation processing is calculated as the target flow rate Q. The intake advance calculation here is an inverse calculation of the intake delay calculation that simulates the time delay from the intake air passing through the throttle valve 26 to the cylinder.

In step B23, the acceleration request calculation unit 4 calculates an acceleration request value REQ indicating the magnitude of the acceleration request required for the engine 10. The acceleration request value REQ is calculated according to, for example, the accelerator opening change rate ΔAPS. In the following step B26, the waste gate control unit 5 sets the waste gate opening D in accordance with the acceleration request value REQ, and calculates the pressure increase amount P _X due to supercharging. As shown in FIG. 5, the waste gate opening degree D is given an opening characteristic that decreases as the acceleration request value REQ increases. Therefore, the boost pressure increases as the acceleration request value REQ increases. Further, the pressure increase amount P _X due to supercharging is calculated as a larger value as the waste gate opening degree D is smaller (squeezed).

In step B30, the pressure ratio calculating section 6b, together with the actual pressure ratio based on the intake manifold pressure P _IM are calculated, time limit pressure ratio is calculated on the basis of the negative pressure target value P _{VAC_LIM.} For example, when the atmospheric pressure P _BP detected by the atmospheric pressure sensor 62 is used as a reference, the actual pressure ratio is expressed as “P _IM / P _BP ”, and the pressure ratio at the time of restriction is “P _{VAC_LIM} / (P _BP + P _X ) ".

In step B40, the flow rate calculation unit 6c, the actual pressure ratio, as a throttle passage flow rate of the intake air corresponding to the respective restriction when the pressure ratio, the actual flow rate U, time limit velocity U _LIM is calculated. Further, the larger one of these flow rates U and U _LIM is selected as the control flow rate U _CTL . Therefore, when the master back negative pressure P _VAC is insufficient, the limiting flow velocity U _LIM (U _LIM > U) becomes the control flow velocity U _CTL . On the other hand, if the master back negative pressure P _VAC is not insufficient, the actual flow rate U becomes the control flow rate U _CTL . In Step B50, the mass flow rate calculation unit 6d calculates the mass flow rate M _MACH per unit area based on the intake air temperature _{TIM and the} like.

In the subsequent step B60, the throttle area calculation unit 6e calculates the target throttle opening area S based on the target flow rate Q, the control flow velocity U _CTL , and the mass flow velocity M _MACH . When the master back negative pressure P _VAC is insufficient, the limit flow velocity U _LIM is larger than the actual flow velocity U, so the value of the target throttle opening S is compared to the case where the actual flow velocity U is used. Becomes smaller. Therefore, when the master back negative pressure P _VAC is insufficient, the throttle opening TH is slightly reduced as compared with a state where the master back negative pressure P _VAC is sufficient.

Further, by the throttle opening TH is squeezed, the intake air quantity introduced into the surge tank 27 from reducing, decreases as the intake manifold pressure P _IM approaches the negative pressure target value P _{VAC_LIM.} As a result, negative pressure is introduced from the surge tank 27 to the master back 43, and the master back negative pressure P _VAC is recovered (pressure is reduced). At this time, the recovery speed of the master back negative pressure P _VAC increases as the intake manifold pressure P _IM becomes lower.

[5. Action]
[5-1. During slow acceleration]
The operation when the waste gate opening degree D and the throttle opening degree TH are limited will be described with reference to FIGS. As shown in FIG. 8 (a), when the accelerator pedal 47 is returned depressed at time t ₀ of the vehicle is running, the target torque of the engine 10 decreases with the accelerator opening degree APS is reduced, in FIG. 8 (c) The throttle opening TH shown also decreases. Further, as shown in FIG. 8 (b), when the brake pedal 44 at time t ₁ is depressed, the throttle opening TH is controlled to the fully closed state.

At this time, as the brake pedal 44 is depressed, the master back negative pressure P _VAC gradually decreases. For example, as indicated by a broken line in FIG. 8E, the master back negative pressure P _VAC gradually increases from time t ₁ . Then, when at time t ₂ is the master back negative pressure P _VAC becomes equal to or higher than the threshold P _{VAC_TH,} it is determined that a state in which the master back negative pressure P _VAC is insufficient. Wastegate opening D In response to this, as shown in FIG. 8 (d), is controlled from time t ₂ to the fully open state. At this time, if the accelerator opening degree APS is fully closed becomes fully closed throttle opening TH, as shown by the solid line in FIG. 8 (e), the intake manifold pressure P _IM gradually decreases. When the master back negative pressure P _VAC is in a state of insufficient in the negative pressure target value calculating section 3, a negative pressure target value P _{VAC_LIM} as the target upper limit of the intake manifold pressure P _IM is calculated.

When the intake manifold pressure P _IM becomes lower than the master back negative pressure P _{VAC at} time t ₃ , the pressure in the master back 43 starts to be released to the surge tank 27 side. As a result, the master back negative pressure P _VAC gradually decreases as shown by the broken line in FIG.
Here, when the accelerator pedal 47 is started to depressed loosen slightly time t _4, the target torque is set in accordance with the accelerator opening degree APS is a conventional control, the throttle opening TH is controlled accordingly. Therefore, as shown by the solid line in FIG. 8 (f), increases in intake manifold pressure P _IM the time t ₄ later, the master back negative pressure P _VAC time until the pressure than (time t ₃ ~t ₅₎ Will be shorter. That is, when the recovery time of the master back negative pressure P _VAC cannot be sufficiently secured and the master back negative pressure P _VAC cannot be lower than the threshold P _{VAC_TH as} shown by the broken line in FIG. There is.

In contrast, in the above control, even the accelerator pedal 47 is depressed, as intake manifold pressure P _IM does not exceed the negative pressure target value P _{VAC_LIM,} waste gate opening D and the throttle opening TH is controlled . For example, the acceleration request calculator 4 calculates the acceleration request value REQ based on the accelerator opening change rate ΔAPS, and controls the waste gate opening D based on the acceleration request value REQ. Here, if the acceleration request value REQ is less than the predetermined value REQ1, the waste gate opening degree D is fully opened. Further, the throttle opening TH is controlled so that the intake manifold pressure P _IM becomes a negative pressure target value P _{VAC_LIM.} As a result, as indicated by a solid line in FIG. _8E , a differential pressure between the intake manifold pressure _PIM and the master back negative pressure P _VAC is secured, and the master back negative pressure P _VAC is recovered.

When the master back negative pressure P _VAC becomes less than the threshold P _{VAC_TH at} time t ₆ , it is determined that the master back negative pressure P _VAC is not insufficient, and the restrictions on the waste gate opening D and the throttle opening TH are released. . At this time, the waste gate opening degree D is controlled according to, for example, the engine rotational speed Ne and the charging efficiency Ec. In the example shown in FIG. 8D, the waste gate opening degree D is controlled to be fully closed. Further, the throttle opening TH is controlled based on the target torque.

[5-2. During sudden acceleration]
Figure 9 (a) ~ (e), the depression speed of the time t ₄ after the accelerator pedal 47 shows the control contents when fast. In this case, if the acceleration request value REQ calculated by the acceleration request calculation unit 4 is equal to or greater than the predetermined value REQ1, as shown in FIG. 9 (d), the waste gate opening degree D according to the magnitude of the acceleration request value REQ. Is controlled small.

On the other hand, the throttle opening TH, it was controlled in the closing direction wastegate valve 17 (i.e., that the supercharging pressure is increased) in consideration of the pressure increase P _X by, intake manifold pressure P _IM negative pressure It is controlled to be the target value P _{VAC_LIM} . Therefore, as compared with the case where the depression speed of the accelerator pedal 47 is slow, as shown in FIG. 9C, the throttle opening TH is controlled to be reduced by the increase in the supercharging pressure. Thus, the negative pressure of the excess and deficiency of the throttle downstream relative to the negative pressure target value P _{VAC_LIM} is canceled, as shown by a solid line in FIG. 9 (e), the intake manifold pressure P _IM negative pressure target value P Converges to _{VAC_LIM} . As a result, the pressure difference between the intake manifold pressure _PIM and the master back negative pressure P _VAC is ensured and the master back negative pressure P _VAC is recovered, as in the case shown by the solid line in FIG.

Thereafter, the master back negative pressure P _VAC is below the threshold P _{VAC_TH} the time t ₆ drops, is determined not to be state master back negative pressure P _VAC is insufficient, the waste gate opening D and the throttle opening TH The restriction is lifted. For example, the waste gate opening degree D is controlled according to the engine rotational speed Ne and the charging efficiency Ec. At this time, since the waste gate opening degree D is not already in the fully open state but is in a state in which the supercharging pressure is slightly increased, the acceleration response is improved as compared with the case shown in FIG.

[5-3. When brake frequency is high]
FIGS. 10A to _10C show the control action when it is determined that the use frequency of the master back 43 is high and the negative pressure target value P _{VAC_LIM} is further set to the low pressure side. In this case, as shown in FIG. 10B, the negative pressure target value P _{VAC_LIM} is set small (on the upper side of the graph). Therefore, as shown in FIG. 10 (a), is controlled smaller throttle opening TH against the accelerator pedal 47, intake manifold pressure P _IM becomes lower pressure than the case shown in FIG. 8 (e). Here, broken lines in FIG. 10 (b), corresponding to the graph of the intake manifold pressure P _IM in FIG. 8 (e).

On the other hand, the recovery speed of the master back negative pressure P _VAC increases as the differential pressure between the master back negative pressure P _VAC and the intake manifold pressure P _IM increases. Therefore, as shown in FIG. 10C, the master back negative pressure P _VAC is quickly recovered. Here, the broken line in FIG. 10C corresponds to the graph of the master back negative pressure P _VAC in FIG. Time t ₇ the master back negative pressure P _VAC is smaller than the threshold value P _{VAC_TH} is located in front of the time t ₆ shown in FIG. 8 (e).

Thus, when the master back 43 is used frequently, the throttle opening TH is controlled so that the recovery time of the master back negative pressure P _VAC is shortened. As shown in FIG. 10 (a), the throttle opening TH at this time is limited to the throttle side more than the throttle opening TH, instead of shortening the period of restriction.

[6. effect]
(1) In the engine control apparatus 1 described above, when the master back negative pressure P _VAC is insufficient, the waste gate opening degree D and the throttle opening degree TH are controlled based on the acceleration request required for the engine 10. At this time, the throttle opening TH is set based on the pressure increase amount P _X of the supercharging pressure generated by changing the waste gate opening D.

That is, the throttle opening TH is controlled to a magnitude that cancels out the excess or deficiency of the negative pressure downstream of the throttle with reference to the negative pressure target value P _{VAC_LIM} of the intake system 20. As a result, as shown in FIG. 9E, the supercharging pressure can be increased while recovering the master back negative pressure P _VAC . Therefore, the acceleration performance after the master back negative pressure P _VAC is recovered to less than the threshold value P _{VAC_TH} can be improved, and both the brake performance and the acceleration performance can be improved.

(2) In the above-described engine control device 1, as shown in FIG. 5, the wastegate opening degree D is controlled to decrease as the acceleration request value REQ increases, that is, the boost pressure is controlled to increase. Such control can further improve the acceleration performance after the master back negative pressure P _VAC is recovered. On the other hand, by decreasing the same time the throttle opening TH and the control to increase the boost pressure can be the intake manifold pressure P _IM to the master back negative pressure P _VAC is restored to the negative pressure target value P _{VAC_LIM.} Therefore, the recovery of the brake performance is not hindered by the supercharging, and the recovery time of the master back negative pressure P _VAC can be shortened.

(3) In the engine control apparatus 1 described above, the negative pressure target value P _{VAC_LIM} is calculated based on the correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , ΔP _{VAC_INC} corresponding to the usage frequency of the master back 43. Further, when the lack of the master back negative pressure P _VAC the throttle opening TH is controlled such intake manifold pressure P _IM becomes equal to or less than the negative pressure target value P _{VAC_LIM.} By such control, the differential pressure between the intake manifold pressure _PIM and the master back negative pressure P _VAC can be secured, and the size of the differential pressure should be set according to the usage frequency of the master back 43. Can do. Therefore, it is possible to optimize the recovery rate and recovery time of the master back negative pressure P _VAC, it is possible to improve the controllability of the master back negative pressure P _VAC.

(4) Regarding the estimation of the usage frequency of the master back 43, the engine control apparatus 1 calculates the correction amount ΔP _{VAC_APS} according to the accelerator opening change rate ΔAPS, for example, as shown in FIG. That is, in the engine control apparatus 1 described above, it is determined that if the driver's intention to accelerate is large, the brake operation is unlikely to be performed thereafter, and if the driver's intention to accelerate is small, the brake operation is likely to be performed thereafter. The

Such a determination makes it possible to estimate the usage frequency of the master back 43 with a relatively high accuracy with a simple calculation configuration without performing a complicated estimation calculation regarding the possibility of a brake operation. Further, the controllability of the master back negative pressure P _VAC can be improved by calculating the negative pressure target value P _{VAC_LIM} based on such a highly accurate estimation result and controlling the throttle opening TH.

(5) In the engine control apparatus 1 described above, for example, as shown in FIG. 4B, ΔP _{VAC_BRK} corresponding to the depression frequency and depression amount of the brake pedal 44 is calculated. That is, in the engine control apparatus 1 described above, if the driver's deceleration frequency and intention to decelerate are large, the brake operation is likely to be performed later, and if the deceleration frequency and intention to decelerate are small, the brake operation may be performed thereafter. Is judged to be low.

Such a determination makes it possible to estimate the usage frequency of the master back 43 with a relatively high accuracy with a simple calculation configuration without performing a complicated estimation calculation regarding the possibility of a brake operation. Further, the controllability of the master back negative pressure P _VAC can be improved by calculating the negative pressure target value P _{VAC_LIM} based on such a highly accurate estimation result and controlling the throttle opening TH.

(6) In the engine control apparatus 1 described above, for example, as shown in FIG. _4C, the correction amount ΔP _{VAC_INC} corresponding to the road surface gradient INC is calculated. That is, in the engine control apparatus 1 described above, the greater the road surface gradient INC (the harder the upward gradient), the lower the possibility that the brake operation will be performed thereafter. The smaller the road surface gradient INC (the harder the downward gradient), the later It is determined that there is a high possibility that the brake operation will be performed. Thus, by referring to the traveling environment of the vehicle, the usage frequency of the master back 43 can be estimated objectively, and the estimation accuracy can be improved. Further, the controllability of the master back negative pressure P _VAC can be improved by calculating the negative pressure target value P _{VAC_LIM} based on such a highly accurate estimation result and controlling the throttle opening TH.

(7) In the engine control apparatus 1 described above, the threshold value P _{VAC_TH} for determining whether or not the master back negative pressure P _VAC is insufficient is set based on the use state of the master back 43. For example, the lower the atmospheric pressure P _BP, set threshold P _{VAC_TH} small, the threshold value P _{VAC_TH} higher atmospheric pressure P _BP is set larger. Further, the value of the threshold value P _{VAC_TH} can be changed according to the accelerator opening change rate ΔAPS, the brake depression frequency, the brake depression amount, the road gradient INC, and the like. Therefore, the balance between the magnitude of the braking assist force by the master back 43 and the number of braking assists that can be executed before the master back negative pressure P _VAC exceeds the threshold value P _{VAC_TH} can be changed and adjusted. You can also do that. Therefore, the braking performance of the vehicle can be easily optimized.

[7. Modified example]
Regardless of the embodiment described above, various modifications can be made without departing from the spirit of the invention. Each structure of this embodiment can be selected as needed, or may be combined appropriately.

In the above embodiment, the waste gate opening degree D is controlled based on the acceleration request value REQ. However, the supercharging pressure control method is not limited to this. For example, it is conceivable to employ a variable capacity turbo device as the turbocharger 16 and control the supercharging pressure by adjusting the flow rate of the exhaust gas flowing into the turbine 16A with a variable vane. At least, when the master back negative pressure P _VAC is insufficient, a supercharging pressure control means for controlling the supercharging pressure based on the acceleration request can be applied. At this time, based on the negative pressure target value P _{VAC_LIM,} by controlling the throttle opening TH to a size to offset the excess and deficiency of the negative pressure in the throttle downstream, to suppress an increase in intake manifold pressure P _IM by supercharging However, supercharging can be continued. Therefore, both brake performance and acceleration performance can be improved.

In the above-described embodiment, the pressure increase amount P _X is calculated based on the waste gate opening degree D, and the throttle opening TH is controlled using the pressure ratio at the time of limitation calculated based on the pressure increase amount P _X. However, various control methods for the throttle opening TH are conceivable. For example, the throttle opening TH may be controlled based on a value _obtained by subtracting the negative pressure target value P _{VAC_LIM} from the boost pressure estimated from the waste gate opening D. Even in such a control configuration, the same effects as those of the above-described embodiment can be obtained.

Further, in the above embodiment, the opening degree limitation in a state where the master back negative pressure P _VAC is insufficient is described in detail based on what controls the throttle opening degree TH based on the target torque of the engine 10. However, the intake air amount control as a base to which the opening degree restriction can be applied is not limited to that based on the target torque. That is, it is possible to apply the above-described opening restriction to intake air amount control that controls the throttle opening TH according to the accelerator opening APS, the engine rotational speed Ne, the vehicle speed, and the like. In this case, for example, the throttle opening degree TH, advance map tripartite relationship of the engine rotational speed Ne and the intake manifold pressure P _IM, is prepared in a formula or the like, the target throttle from the engine speed Ne and the negative pressure target value P _{VAC_LIM} The opening may be calculated.

In the above-described embodiment, the correction amounts ΔP _{VAC_APS} , ΔP _{VAC_BRK} , ΔP _{VAC_INC} corresponding to the use frequency of the master back 43 are calculated based on the accelerator opening change rate ΔAPS, the brake fluid pressure BRK, the road surface gradient INC, and the like. However, a calculation configuration for estimating the usage frequency of the master back 43 itself may be used. For example, it is conceivable to calculate the magnitude of the possibility that the master back 43 will be used (the possibility that the brake operation will be performed) within a few seconds from that point of time as the expected value.

The expected value is set higher as the accelerator opening change rate ΔAPS is larger. Similarly, the lower the brake depression frequency, the smaller the brake depression amount, and the smaller (negative) the road surface gradient INC, the higher the setting. On the other hand, it is _assumed that the negative pressure target value P _{VAC_LIM} is set closer to a lower pressure (the negative pressure target value P _{VAC_LIM} is smaller) as the expected value is higher. With such a configuration, it is possible to realize control that provides the same effects as those of the above-described embodiment.

DESCRIPTION OF SYMBOLS 1 Engine control apparatus 2 Negative pressure determination part (determination means)
3 Negative pressure target value calculation unit 3a Acceleration correction unit (estimating means)
3b Brake correction unit (estimating means)
3c Road slope correction unit (estimating means)
3d totaling unit (calculation means)
4 Acceleration request calculation unit (acceleration request calculation means)
5 Wastegate control unit (supercharging pressure control means)
6 Throttle control part (throttle control means)
10 Engine 17 Wastegate valve 26 Throttle valve 43 Master back (brake booster)
44 Brake pedal
REQ Request acceleration value
D Wastegate opening
TH throttle opening
P _IM intake manifold pressure
P _VAC master back negative pressure
P _{VAC_TH} threshold
P _{VAC_LIM} negative pressure target value

Claims (7)

Calculating means for calculating a negative pressure target value downstream of the throttle of the intake system when a master back negative pressure of a brake booster connected downstream of the throttle of the intake system of the engine is insufficient;
Supercharging pressure control means for controlling a supercharging pressure that is a pressure upstream of the throttle of the engine based on an acceleration request required for the engine;
Based on the acceleration request required for the engine, the negative pressure excess downstream of the intake system throttle caused by the change in the supercharging pressure controlled by the supercharging pressure control means with the negative pressure target value as a reference. Throttle control means for controlling the throttle opening of the engine so that the shortage is offset;
An engine control device comprising: The supercharging pressure control means increases the supercharging pressure as the acceleration request increases.
2. The engine control apparatus according to claim 1, wherein the throttle control means decreases the throttle opening as the acceleration request is larger. Comprising estimation means for estimating the frequency of use of the brake booster,
The engine control apparatus according to claim 1, wherein the calculation unit calculates the negative pressure target value based on the use frequency estimated by the estimation unit. 4. The engine control apparatus according to claim 3, wherein the estimating means estimates the use frequency based on an accelerator opening change rate. The engine control apparatus according to claim 3 or 4, wherein the estimation means estimates the use frequency based on a road surface gradient. The engine control device according to any one of claims 3 to 5, wherein the estimation means estimates the use frequency based on a number of depressions or a depression amount of a brake pedal. When the master boost negative pressure of the brake booster is less than a threshold set based on the use state of the brake booster, the brake booster includes a determination unit that determines that the master back negative pressure is insufficient. The engine control device according to any one of claims 1 to 6.

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