JP2007270788A - Control device of multicylinder 4-cycle engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure certainty of starting, by surely preventing even self-ignition in a cylinder, while not conventionally suspiciously viewed, by taking a countermeasure for surely preventing the self-ignition, when an operation state after restarting is put in an easily self-ignitable environment. <P>SOLUTION: In a reverse rotation starting system, after burning a stopping time expansion stroke cylinder after the restarting, when a stopping time intake stroke cylinder meets with a second compression stroke, fuel is injected in the middle period of its compression stroke, and is ignited in the predetermined timing. Afterwards, the fuel injection timing is changed in response to an engine speed detected in a predetermined period up to fuel injection time to the stopping time intake stroke cylinder from combustion time in the stopping time expansion stroke cylinder to a cylinder meeting with a compression stroke in the third place. When the detected engine speed is a reference engine speed or more, the fuel is injected up to the first half of the compression stroke at least from the first half of an intake stroke. When the engine speed is less than a reference engine speed N<SB>ST</SB>, the fuel injection timing is retarded up to the middle period of the compression stroke. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a control device for a multi-cylinder four-cycle engine, and more particularly to a control device for a multi-cylinder four-cycle engine suitable for an automatic stop system using electric drive means.

For example, as disclosed in Patent Documents 1 to 3, an engine control system (automatic stop) that automatically stops the engine during idling (so-called idle stop) for the purpose of reducing fuel consumption and suppressing CO ₂ emissions. System) is known.

  In such an automatic stop system, the engine must be started immediately in response to an engine restart request such as a start operation. However, as disclosed in Patent Document 1, in a general starting method in which the engine is started through cranking by the electric drive means, there is a tendency that the starting time becomes slightly longer. In addition, there was a problem that the noise accompanying the cranking and the engine blow-up (rapid increase in engine speed more than necessary) give a sense of incongruity.

  Furthermore, if the engine is assisted and restarted every time when the engine is in an idle state, the number of start-ups is much higher than in a normal system that starts only when the ignition switch is operated. Therefore, the electric drive means is required to have extremely high durability, and there is a problem that unnecessary cost increases.

  Therefore, in recent years, for example, by injecting fuel into a stop-time expansion stroke cylinder that is in an expansion stroke in a stopped state, such as in-cylinder direct injection engines disclosed in Patent Documents 2 and 3, ignition and combustion are performed. An engine that starts the engine with its own power without borrowing the power of electric drive means has been developed.

In particular, in Patent Document 3, the engine is temporarily reversed by a predetermined crank angle by combustion in a stop-time compression stroke cylinder that is in a compression stroke at the time of stop, and then reversely rotated to reverse the engine by combustion in the stop-time expansion stroke cylinder. Adopting the start-up method, increasing the cylinder pressure of the expansion stroke cylinder at the time of stopping when approaching the atmospheric pressure, and then performing combustion in the cylinder so as to increase the output by the combustion in the expansion stroke cylinder at the time of stop I have to.
JP 2004-100616 A JP-A-2005-42677 JP-A-2005-180208

  In the initial restart state in the above-described reverse start type automatic stop system, it is necessary for the two cylinders to exceed the compression stroke due to combustion of the expansion stroke cylinder when stopped, and the engine speed is relatively low. Therefore, until the two cylinders exceed the compression stroke after the restart, that is, until the second compression stroke is exceeded, the heat receiving time from the combustion chamber wall of each cylinder becomes longer, the intake air temperature becomes higher, The heating time of the fuel injected into the cylinder also becomes longer, and the activation of the injected fuel is promoted. As a result, self-ignition tends to occur. When such self-ignition occurs in a cylinder that has reached the compression stroke, there is a problem that the engine is driven in the reverse direction and fails to restart.

  Therefore, in Patent Document 3, the fuel injected in the stop intake stroke cylinder that was in the intake stroke at the time of stop is retarded at the first timing in the compression stroke after the stop intake stroke cylinder is restarted. The ignition timing is retarded after elapse of the top dead center, thereby preventing self-ignition in the intake stroke cylinder at the time of stop.

  However, self-ignition in the initial restart state reaches the third compression stroke when the in-cylinder temperature is extremely high, the rotational speed is extremely slow, or when fuel leaks from the fuel injection valve, etc. As a result of earnest research of the present invention, it has been clarified that it can also occur in the cylinder.

  It is an object of the present invention to provide a control device for a multi-cylinder four-cycle engine that can reliably prevent self-ignition in a cylinder that has not been regarded as a problem so far and can ensure starting reliability.

  In order to solve the above-mentioned problems, the present invention is based on the fact that when a condition for restarting a multi-cylinder four-cycle engine that has been automatically stopped is satisfied, the above-mentioned problem is once caused by combustion in a stop-time compression stroke cylinder that was in a compression stroke at the time of stop. In a control apparatus for a multi-cylinder four-cycle engine, in which the engine is reversely rotated by a predetermined crank angle, and then the engine is rotated forward and restarted by combustion in the expansion stroke cylinder at the stop that was in the expansion stroke at the time of stop. On the basis of the rotational speed and the crank position detected by the operating state detecting means, the electric driving means capable of at least starting assistance, the operating state detecting means capable of detecting at least the engine rotational speed and the crank position of each cylinder. Fuel injection control means for controlling the air-fuel ratio of fuel injected into each cylinder and the injection timing, and the fuel injection When the stop intake stroke cylinder that was in the intake stroke at the time of stoppage first reaches the compression stroke after the restart, fuel is injected in the compression stroke of the stop intake stroke cylinder, and the intake at the stop For a cylinder that reaches the compression stroke after the stroke cylinder, the engine detected by the operating state detection means in a predetermined period from the time of combustion in the stop expansion stroke cylinder to the time of fuel injection to the stop intake stroke cylinder When the rotational speed is equal to or higher than a predetermined reference rotational speed, fuel is injected so that the fuel injection timing is delayed as the engine rotational speed is low during the period from the first half of the intake stroke to the first half of the compression stroke at the latest. If the value is less than, the fuel is injected in the middle of the compression stroke. In this aspect, in the reverse rotation start system, the engine that has been reversely rotated by the combustion in the compression stroke cylinder at the time of stop is turned forward by burning the expansion stroke cylinder at the time of restart after the restart. In addition, after the burned-down-compression cylinder after the combustion has passed the first compression stroke, the stationary-intake-stroke cylinder reaches the second compression stroke. In the stop-time intake stroke cylinder, fuel is injected during the compression stroke and ignited at a predetermined timing. After that, for the cylinder that reaches the third compression stroke, according to the rotational speed detected during a predetermined period from the time of combustion in the stop expansion stroke cylinder to the time of fuel injection to the stop intake stroke cylinder The fuel injection timing is changed. When the rotational speed detected during the predetermined period is equal to or higher than the reference rotational speed, fuel is injected from the first half of the intake stroke to the first half of the compression stroke at the latest. If the rotation speed exceeds the reference rotation speed, the second compression top dead center can be passed, and the self-ignition in the cylinder that reaches the compression stroke thereafter will not occur, so the fuel injection timing is advanced. By doing so, it becomes possible to improve the output. On the other hand, if it falls below the reference rotational speed, there is still a possibility that self-ignition in the compression stroke may still occur. In that case, by making the fuel injection timing retard to the middle stage of the compression stroke, the self-ignition can be ensured. It is possible to prevent such a situation.

  In a preferred aspect, the engine is a four-cylinder engine, and the fuel injection control means is configured so that each of the intake strokes after the stop-time intake stroke cylinder finishes the first compression stroke, regardless of the engine speed. The fuel is injected during the intake stroke of the cylinder. In this aspect, after all the cylinders have completed the first compression stroke, paying attention to the fact that they are already in an operation state in which self-ignition is unlikely to occur in the compression stroke, and by performing fuel injection during the intake stroke, Can be improved.

  In a preferred aspect, the operating state detecting means has a function capable of estimating an in-cylinder temperature of the engine, and the fuel injection control means is a period until the intake stroke cylinder at the time of stop passes the first compression stroke. In addition, when the in-cylinder temperature estimated by the operating state detection means is equal to or higher than a predetermined temperature, the injection timing is retarded in the middle of the compression stroke regardless of the engine speed. In this aspect, for the period until the stop-time intake stroke cylinder shifts to the compression stroke, pay attention to the in-cylinder temperature of the engine, and when the in-cylinder temperature of the engine is high, the fuel injection timing regardless of the engine speed. Is retarded in the middle of the compression stroke in order to prevent self-ignition more reliably.

  In a preferred aspect, the operating state detecting means determines that the in-cylinder temperature is higher as the elapsed time after the engine is automatically stopped is closer to a predetermined time within 60 seconds. In this aspect, based on the knowledge that the air temperature in the cylinder rapidly rises within a predetermined time of 60 seconds or less after the automatic stop of the engine, the in-cylinder temperature becomes closer to the predetermined time when the restart condition is satisfied. Since the operation state detecting means is configured so that it is determined that the engine is high, it is possible to reliably prevent knocking in a temperature environment in which self-ignition is likely to occur.

  In a preferred aspect, there is provided ignition control means for executing ignition in each cylinder at a predetermined timing based on the determination of the operating state determination means, and the ignition control means is configured such that the stop-time intake stroke cylinder first performs a compression stroke. When it reaches, ignition is performed in the compression stroke cylinder at the time of stop after the compression top dead center elapses. In this mode, ignition in the intake stroke cylinder at the time of stop when the intake air temperature tends to be the highest is retarded after the compression top dead center elapses, so that the intake stroke cylinder blows up at the stop intake stroke cylinder. It is possible to reliably prevent the occurrence of an increase in

  In a preferred aspect, the ignition control means advances the ignition timing to a predetermined timing before the compression top dead center when fuel is injected in the compression stroke in an operation state in which fuel injection in the intake stroke is possible. is there. In this mode, even if there is a sufficient rotation speed, if the intake stroke is not in time after the determination timing of the rotation speed, fuel injection is executed in the compression stroke. Since there is little possibility of ignition, the ignition timing is advanced before the compression top dead center to obtain a high output so that both self-ignition prevention and output improvement are achieved.

  As described above, according to the present invention, when the operation state after restart is in an environment in which self-ignition is likely to occur, it is possible to take measures that can reliably prevent self-ignition. There is a remarkable effect that it is possible to reliably prevent self-ignition in a cylinder that has not been viewed, and to ensure start-up reliability.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is a schematic configuration diagram of an engine control system according to an embodiment of the present invention, and FIG. 2 is a schematic diagram showing configurations of an intake system and an exhaust system of the engine control system.

  Referring to the drawings, the engine control system includes an engine body 1 including a cylinder head 10 and a cylinder block 11, and a control unit (ECU) 2 for controlling the engine body 1.

  The engine body 1 is provided with four cylinders 12A to 12D. As shown in FIG. 1, pistons 13 connected to the crankshaft 3 are inserted into the cylinders 12A to 12D, respectively. Thus, a combustion chamber 14 is formed above the piston 13 in each of the cylinders 12A to 12D.

  In general, in a multi-cylinder four-cycle engine, each cylinder performs a combustion cycle including intake, compression, expansion, and exhaust strokes with a predetermined phase difference. In the case of the four-cylinder engine of the present embodiment, the first cylinder 12A, the second cylinder 12B, the third cylinder 12C, and the fourth cylinder 12D from the one end side in the cylinder row direction are referred to as the first cylinder (# 1) and the third cylinder. (# 3) Combustion is performed with a phase difference of 180 degrees in crank angle in the order of the fourth cylinder (# 4) and the second cylinder (# 2). Further, in this embodiment, a cylinder that was in the compression stroke during the automatic engine stop is referred to as a stop compression stroke cylinder, and a cylinder that was in the expansion stroke is referred to as a stop expansion stroke cylinder (similarly, the cylinder that was in the intake stroke is stopped). The cylinder in the intake stroke and the exhaust stroke is referred to as a stop exhaust stroke cylinder).

  Referring to FIG. 1, an ignition plug 15 for igniting and burning an air-fuel mixture in the combustion chamber 14 is provided at the top of each combustion chamber 14 of each of the cylinders 12A to 12D. The electrode at the tip of each spark plug 15 is disposed so as to face the combustion chamber 14. Further, a fuel injection valve 16 is provided on the side of the combustion chamber 14 (rightward in FIG. 1) with the nozzle hole at the tip facing the combustion chamber 14. The fuel injection valve 16 includes a needle valve and a solenoid (not shown) and is driven to open for a time corresponding to the pulse width in response to the input of a pulse signal from the control unit 2. The fuel is injected directly into the cylinders into the cylinders 12A to 12D. The fuel injection direction is adjusted so as to be directed to the vicinity of the electrode of the spark plug 15.

  Although not shown, fuel is supplied to the fuel injection valve 16 via a fuel supply passage or the like by a fuel pump, and the fuel supply pressure is in the middle of the compression stroke of each cylinder 12A to 12D. Thereafter, the pressure is set higher than the pressure in the combustion chamber 14 so that fuel can be injected into the high-pressure in-cylinder combustion chamber 14.

  An intake port 17 and an exhaust port 18 that open toward the combustion chamber 14 are provided in the upper part of the combustion chamber 14 of each of the cylinders 12A to 12D. An intake valve 19 and an exhaust valve 20 are disposed in these ports 17 and 18, respectively. The intake valve 19 and the exhaust valve 20 are driven by a valve operating mechanism including a camshaft (not shown). The opening timings of the intake valve 19 and the exhaust valve 20 by the valve operating mechanism are set for each of the cylinders 12A to 12D so that the cylinders 12A to 12D perform a combustion cycle with a predetermined phase difference.

  As shown in FIG. 2, an intake passage 21 and an exhaust passage 22 communicate with the intake port 17 and the exhaust port 18, respectively. The downstream side of the intake passage 21 close to the intake port 17 forms a branched intake passage 21a independent for each of the cylinders 12A to 12D, and the upstream end of each branched intake passage 21a communicates with the surge tank 21b. . The intake passage 21 upstream of the surge tank 21b is a common intake passage 21c common to the cylinders 12A to 12D. In this common air passage 21c, for example, a throttle valve 23 for restricting the intake flow by adjusting the passage sectional area by a butterfly valve and an actuator 24 for driving the throttle valve 23 are disposed. Further, an air flow sensor 25 for detecting the intake air amount and an intake pressure sensor 26 for detecting the intake air pressure (negative pressure) are disposed upstream and downstream of the throttle valve 23.

  Next, an alternator 28 that is drivingly connected to the crankshaft 3 by a belt or the like is attached to the engine body 1. The alternator 28 includes a regulator circuit 28a that changes the output voltage by controlling the current of the field coil and thereby adjusts the amount of power generation. A control command from the control unit 2 is supplied to the regulator circuit 28a. By inputting (for example, voltage), basically, the amount of power generation is controlled according to the electric load of the vehicle electrical component and the in-vehicle battery voltage. When the power generation amount of the alternator 28 is changed in this way, the driving force, that is, the magnitude of the external load of the engine body 1 changes accordingly.

  Next, a catalyst 37 for purifying exhaust gas is disposed downstream of the collecting portion of the exhaust passage 22 of each of the cylinders 12A to 12D. The catalyst 37 is, for example, a so-called three-way catalyst in which the purification rate of HC, CO, and NOx is extremely high when the air-fuel ratio of the exhaust gas is in the vicinity of the theoretical air-fuel ratio, and this is a relatively high oxygen concentration in the exhaust gas. It has an oxygen storage capacity for storing it in a high oxygen excess atmosphere. When the oxygen concentration is relatively low, the stored oxygen is released and reacted with HC, CO and the like. Note that the catalyst 37 is not limited to a three-way catalyst, and may be any catalyst as long as it has an oxygen storage capacity as described above. For example, the catalyst 37 may be a so-called lean NOx catalyst that can purify NOx even in an oxygen-excess atmosphere.

  Next, the engine body 1 is provided with two crank angle sensors 30 and 31 for detecting the rotation angle of the crankshaft 3, and the engine rotation speed Ne is determined based on the detection signal output from one crank angle sensor 30. The rotation direction and phase of the crankshaft 3 are detected on the basis of detection signals out of phase output from the crank angle sensors 30 and 31 as well as being detected.

  Next, the engine body 1 is provided with a cam angle sensor 32 for detecting a specific rotational position for cylinder identification provided on the camshaft, and a water temperature sensor 33 for detecting the coolant temperature of the engine. Is provided with an accelerator opening sensor 34 for detecting the accelerator opening corresponding to the accelerator operation amount of the driver.

  The control unit 2 is a microprocessor that comprehensively controls the operation of the engine. The engine according to this embodiment is configured to automatically stop the fuel by stopping fuel injection into each cylinder 12A to 12D at a predetermined timing (fuel cut) when a preset automatic stop condition is satisfied ( (Idle stop control) and a control (combustion restart control) that automatically restarts the engine when a restart condition is satisfied, for example, when the driver performs an accelerator operation after the engine is automatically stopped. It is configured as follows. In order to realize such control, the control unit 2 includes an air flow sensor 25, an intake pressure sensor 26, an intake air temperature sensor 29, crank angle sensors 30, 31, a cam angle sensor 32, a water temperature sensor 33, and an accelerator opening sensor 34. Are output to the fuel injection valve 16, the actuator 24 of the throttle valve 23, the ignition device 27, and the regulator circuit 28a of the alternator 28, respectively. Thereby, the control unit 2 functionally constitutes an operation state detection means, a piston stop position identification means, a fuel injection control means, and an ignition control means.

  Next, control for automatically stopping the engine body 1 by the control unit 2 will be described.

  The automatic stop control of the engine body 1 is based on the vehicle speed, the operating condition of the brake, the engine water temperature, and the like, as already disclosed in Patent Document 3 described in the prior art document column. When one of the cylinders 12 (for example, the first cylinder 12A) is specified, it is determined whether or not a predetermined condition for stopping the engine main body 1 is satisfied. If the determination condition is satisfied, each cylinder is determined. The fuel injection to 12A to 12D is stopped, the throttle valve 23 is opened to a set opening degree, and sufficient scavenging is performed. The engine body 1 controls the throttle valve 23 and the alternator 28 based on the speed. The load on the engine body 1 is adjusted. As a result, the engine body 1 gradually decelerates while repeating up and down, and the stop-time compression stroke cylinder 12A (stop-time expansion stroke cylinder 12B) stops in a desired stop range (single stop range shown in FIG. 4) R. To control.

  FIG. 3 is an explanatory diagram showing piston stop positions of the stop expansion stroke cylinder and the stop compression stroke cylinder for the automatic engine stop control.

  Referring to FIG. 3, the memory of control unit 2 has a bottom dead center limit (θ1 of compression stroke cylinder 12A when stopped, θ4 of expansion stroke cylinder when stopped) and a top dead center limit that can be restarted by combustion in advance. The combustion restartable range A determined by (θ4 of the stop stroke compression cylinder 12A, θ1 of the stop expansion stroke cylinder) is determined. The piston 13 stops within the combustion restartable range A based on the above-described control. Among the combustion restart range, the stop compression stroke cylinder is from 90 ° CA before top dead center. However, it is preferable to stop in the slightly upper range. In the example of the present embodiment, as indicated by θ2 to θ3 in FIG. 3, the compression stroke cylinder at the stop is from 60 ° CA to 80 ° CA before top dead center (therefore, the expansion stroke cylinder at stop is 100 ° CA after top dead center). From the single combustion stop range R to the top dead center side of the single combustion stop range R up to θ1 in FIG. 3 (the bottom dead center side in the case of a stop expansion stroke cylinder). And the control unit 2 determines the predetermined range on the bottom dead center side (top dead center side in the case of the expansion stroke cylinder at the time of stop) as the combined combustion stop range and the remaining range as non-combustible restart ranges NG1 and NG2. The standard is set.

  The single combustion stop range R refers to a stop position where the engine main body 1 can be restarted only by combustion without using a starter motor (not shown) at the time of restart. When the piston 13 of the stop expansion stroke cylinder is in the single combustion stop range R, the amount of air in the cylinder increases and sufficient combustion energy is obtained. Further, since the scavenging is promoted by increasing the opening K of the throttle valve 23 during the engine stop operation period, a sufficient amount of fresh air is supplied to the catalyst 37. Therefore, the oxygen storage amount of the catalyst 37 is sufficiently large while the engine is stopped. Further, a predetermined amount of air is secured in the compression stroke cylinder at the time of stop, and combustion energy is obtained to such an extent that the crankshaft 3 can be slightly reversed in the first combustion. In addition, by securing a large amount of air in the expansion stroke cylinder at the time of stop, it is possible to generate sufficient combustion energy for causing the crankshaft 3 to rotate in the forward direction and to reliably restart the engine.

  Therefore, in the present embodiment, when the engine body 1 is automatically stopped at the time of idling, first, the fuel is cut at a predetermined rotational speed slightly higher than the idle rotational speed so that the scavenging of each cylinder 12A to 12D is sufficiently performed. At the same time, the throttle valve 23 is opened for a predetermined period thereafter, and control is performed to achieve a preset opening degree. The throttle valve 23 is closed at an appropriate timing set in advance. As a result, the amount of air drawn into the stop-time expansion stroke cylinder 12B and the stop-time compression stroke cylinder 12A is sufficiently increased, and the amount of air in the expansion stroke cylinder 12B is slightly larger than that of the compression stroke cylinder 12A. As a result, the piston 13 of the expansion stroke cylinder 12B is slightly moved closer to the bottom dead center (bottom dead center) from the center of the stroke due to the balance of the compression pressure of the air in the two cylinders 12A and 12B driven at the time of restart. It stops within a single combustion stop range R suitable for starting.

  Next, the combined combustion stop ranges A1 and A2 are stop ranges that can be restarted by using a starter motor (not shown) at the time of restart.

  Further, the combustion restart impossible range NG1, NG2 refers to a stop range where reverse rotation restart by combustion is not possible.

These stop range R, A1, A2, NG1, NG2, after the control unit 2 estimates the stop range, is identified by the stop range determining flag F _ST is set, then the restart control engine body 1 to be described The restart control is executed according to each case. Here, the stop position determination flag _FST indicates a stop state when the engine body 1 is automatically stopped. In the case of 1, the stop position determination flag _FST indicates that the piston 13 is stopped in the single combustion stop range R. In the case other than 1, it indicates that it is out of the single combustion stop range. The initial value of the stop position determination flag _FST is set to 1.

  Next, a description will be given of a case where the engine body 1 that has been automatically stopped at the time of idling is automatically restarted.

  FIG. 4 is a schematic diagram showing an engine starting procedure in the engine control system.

  Referring to FIG. 4, when restarting the engine, as a general rule, the engine body 1 is started by itself without borrowing the power of a starter motor (not shown). In this embodiment, FIG. As schematically shown in FIG. 4D, first, the first combustion is performed in the compression stroke cylinder 12A at the time of stop, and the piston 13 is pushed down to slightly reverse the crankshaft 3 (see FIG. Thus, the piston 13 of the expansion stroke cylinder 12B at the time of stop is raised to compress the air-fuel mixture in the cylinder 12B (see FIG. 4B). Then, the air-fuel mixture in the stop expansion stroke cylinder 12B, which has been compressed in this way and whose temperature and pressure are increased, is ignited and burned, thereby giving the crankshaft 3 torque in the forward direction, and The main body 1 is started. In order to start the engine body 1 by itself, the torque in the forward rotation direction is applied to the crankshaft 3 as much as possible by the combustion of the expansion stroke cylinder 12B at the time of stop, and as shown in FIG. The stop compression stroke cylinder 12A must overcome the compression reaction force (compression pressure) and exceed the top dead center. Therefore, in order to reliably start the engine body 1, it is necessary to ensure sufficient air for combustion in the stop-time expansion stroke cylinder 12B. On the other hand, the presence of considerable air in the expansion stroke cylinder 12B at the time of restart prevents the air from being strongly compressed during reverse rotation. This is because the compression reaction force of the compressed air acts in the direction of pushing back the piston 13 of the expansion stroke cylinder 12B at the time of stop.

  Therefore, in the present embodiment, control is performed to increase the compression amount (increase the density) of the air in the stop expansion stroke cylinder 12B by delaying the fuel injection timing to the stop expansion stroke cylinder 12B. When the fuel injection timing is delayed, the fuel is injected into the cylinder in which the cylinder air is compressed to some extent, and the compression pressure is reduced by the latent heat of vaporization. Therefore, if the energy is in the same engine reverse direction, the piston 13 can move closer to the top dead center (increase in piston stroke), and the density of compressed air can be further increased.

  Next, after the normal rotation, the reaction force of the burned gas remaining in the compression stroke cylinder at the stop time can cause a decrease in the torque after the normal rotation. For this reason, in the present embodiment, after combustion in the stop expansion stroke cylinder, fuel is injected into the stop compression stroke cylinder 12A, thereby reducing the pressure in the stop compression stroke cylinder 12A after reverse rotation due to latent heat of vaporization. The reduction in torque is suppressed (see FIG. 4C).

  Further, in the stop-time intake stroke cylinder 12C that reaches the compression stroke after combustion in the stop-time expansion stroke cylinder 12B, the ignition timing is retarded after compression top dead center to prevent so-called blow-up (FIG. 4D). )reference).

  When the engine main body 1 is forcibly stopped and then automatically restarted as described above, if auto-ignition occurs in a cylinder (mainly, the intake stroke cylinder at the time of stoppage) that reaches the compression stroke after burning the expansion stroke cylinder at the time of stoppage. In this cylinder, the piston receives a large reaction force, knocking occurs and the restart fails. Therefore, in this embodiment, various measures are taken in order to prevent self-ignition at the time of restarting combustion.

  First, as one of the countermeasures for self-ignition, there is management of the in-cylinder temperature.

  FIG. 5 is a graph showing the relationship between the elapsed time from the engine stop and the in-cylinder temperature, and is an estimated value of the in-cylinder temperature change when the in-cylinder temperature when the engine is stopped is 80 ° C. Referring to FIG. 5, when the engine is completely stopped, the in-cylinder temperatures of cylinders 12A to 12D change with the temperature characteristics shown in FIG. After the engine main body 1 is automatically stopped, when the engine main body 1 is completely stopped, the flow of the cooling water is also stopped, so that the in-cylinder temperature rapidly rises immediately after the stop. Then, it peaks at about 10 seconds after the engine stops, and then gradually decreases. Although this characteristic varies depending on the temperature of the cooling water (engine water temperature), the outside air temperature (intake air temperature), etc., it can be determined by experiment for each specification of the engine body 1. 5 is stored for each specification of the main body 1, and a range of about 10 seconds after the engine is stopped is set as a predetermined stop time range. In this predetermined stop time range, the intake air of the engine main body 1 is stored. It is determined that the predetermined warm state is determined when the air temperature of the passage rapidly rises, and that the in-cylinder temperature is determined to be higher as the restart time is closer to the predetermined stop time range. Therefore, measures are taken to prevent self-ignition. In the present embodiment, the control map M6 in FIG. 13 is embodied as a map corresponding to FIG.

  FIG. 6 is a graph showing the relationship between the stop position of the engine that has been automatically stopped and the self-ignition occurrence timing.

  Next, referring to FIG. 6, in the warm state (warm-up: for example, when the detected value of the intake air temperature sensor 29 is 100 ° C. or more), the stop position of the stop-time compression stroke cylinder 12 </ b> A is before top dead center. When there is unburned fuel in the compression stroke cylinder 12A at the time of stop when it is at the bottom dead center side than 90, the self-compression cylinder 12A at the stop compression stroke after the combustion of the expansion stroke cylinder 12B at the stop is almost independent of the air-fuel ratio. As a result of experiments conducted by the present inventors, it became clear that ignition tends to occur. For this reason, in this embodiment, when the piston 13 exists in the allowable range of the piston stop position beyond θ3 to θ4, the engine body 1 is restarted after forcing the piston position. Like to do. In addition, after the combustion in the stop expansion stroke cylinder 12B is completed, the fuel is injected into the stop compression stroke cylinder 12A, thereby reducing the in-cylinder pressure by atomization of the injected fuel. However, in certain cases, the fuel injection is stopped, or additional fuel is injected to prevent self-ignition so as to prevent self-ignition in the stop-time compression stroke cylinder 12A. ing.

  Next, there is a fuel leak as a matter that requires measures for preventing self-ignition. In the direct injection engine in which the fuel injection valve 16 faces the combustion chamber 14 as in the present embodiment, the fuel leaking from the injection hole of the fuel injection valve 16 is in the cylinders 12A to 12D when the engine body 1 is stopped. As a result, an air-fuel mixture is formed. When restarting, there may be a case where self-ignition occurs in the stop-time intake stroke cylinder 12C.

  7 and 8 are graphs showing the relationship between the injection timing and self-ignition for each fuel leak amount in the compression stroke of the stop-time intake stroke cylinder 12C. In each figure, Ag1 represents a range in which self-ignition did not occur, Ag2 to Ag4 represent fuel injection timing ranges in which self-ignition occurred, and Ag2 represents 10 ° to 20 ° CA after the top dead center has elapsed. CA and Ag3 indicate 10 ° CA to 0 ° CA after the top dead center has elapsed, and Ag 4 indicates 0 ° CA to 10 ° CA before the top dead center has elapsed. FIG. 7 is a graph when the temperature in the surge tank 21b is 75 ° C., and FIG. 8 is a graph when the temperature is 100 ° C.

  As shown in FIGS. 7A to 7F, when there is no fuel leak, the area of the range Ag4 where the self-ignition is likely to occur as the fuel injection timing becomes the first half from the middle of the compression stroke (about 96 ° CA). Tend to be wide. On the other hand, even when the fuel injection timing is the same, when the amount of fuel leakage is large (A / F is 30 or less), the fuel is over-rich, and thus self-ignition hardly occurs. Further, comparing (A) in FIG. 7 and (A) in FIG. 8 and (B) in FIG. 7 (C) and FIG. The range Ag4 where ignition is likely to occur tends to be wide. Therefore, in the present embodiment, when fuel is injected in the middle of compression, the fuel is injected particularly at about 96 ° CA before the compression top dead center, and the intake stroke cylinder at the time of stop according to the leak amount By injecting additional fuel into 12C, self-ignition is prevented.

  FIG. 9 is a timing chart showing the fuel injection timing.

  Referring to FIG. 9, in the present embodiment, when fuel is injected into the stop-time intake stroke cylinder 12C that reaches the first compression stroke at the time of restart, as shown in FIG. 9, the fuel is injected into the compression stroke. In addition, the additional injection is performed in the compression stroke. The total fuel injection amount is set so that the in-cylinder air-fuel ratio falls within the combustible range (rich limit is 5 or more). At this time, the subsequent fuel injection amount is embodied by a control map M6 shown in FIG.

  Next, the start control procedure will be described.

  FIG. 10 is a flowchart showing a main flow of restart control.

  Referring to FIG. 10, the restart control of the engine main body 1 according to the present embodiment is based on starting the engine main body 1 by itself as described above. However, when a starter motor is used in combination as a fail-safe function. In addition, the case where a starter motor is used together from the beginning is also included.

In this flow, the control unit 2 first determines whether or not a restart condition is satisfied (step S60). The restart condition is when the brake is released to start from a stopped state, when an accelerator operation or the like is performed, or when the engine needs to be operated for the operation of an air conditioner or the like. When the restart condition is satisfied, it is determined whether or not the engine body 1 is stopped (step S61). If the accelerator is depressed while the engine is not stopped, it is determined whether or not the engine rotational speed Ne at that time has reached a predetermined allowable rotational speed Ne _min (step S62). If the engine does not reach the predetermined rotation speed in this flow, it waits for the engine to stop, and if it exceeds the allowable rotation speed, it switches to normal operation as it is (step S63) and ends the processing. To do.

  Next, when it is determined in step S61 that the engine body 1 is stopped, it is first determined whether or not the engine is in an operation state that requires start assist (step S64). Based on this determination, the start assist is determined. Is not required (YES in step S64), the combustion restart control subroutine (step S110), and when start assist is required (NO in step S64), the assist combined restart control subroutine (S120) is executed. become. The control unit 2 immediately executes the assist combined restart control subroutine S120. Note that the assist combined restart control subroutine S120 itself can be executed by a known control technique, and therefore, detailed description thereof is omitted.

  Next, the combustion restart control subroutine S110 will be described.

  FIGS. 11 to 14 are flowcharts showing the combustion restart control subroutine S110, and FIG. 15 is a timing chart based on the flowcharts of FIGS.

  First, referring to FIGS. 11 and 15, the control unit 2 estimates the in-cylinder temperatures of the respective cylinders 12A to 12D from the water temperature, the stop time, the intake air temperature, and the like (step S1101). Then, the control unit 2 calculates the amount of air in the stop compression stroke cylinder 12A and the stop expansion stroke cylinder 12B based on the detected stop position of the piston 13 (step S1102). That is, the combustion chamber volumes of the stop compression stroke cylinder 12A and the stop expansion stroke cylinder 12B are obtained from the stop position of the piston 13, and when the engine is stopped, after the engine has been rotated several times after the fuel injection is stopped. Since the engine is stopped, the stop expansion stroke cylinder 12B is also filled with fresh air, and the inside of the stop compression stroke cylinder 12A and the stop expansion stroke cylinder 12B is substantially at atmospheric pressure while the engine is stopped. The amount of fresh air is obtained from the combustion chamber volume.

Next, the control unit 2, by reading the value of the restart ID flag F _ST, the piston stop position, alone combustion stop range R in the stop-state compression-stroke cylinder 12A (BTDC 60-80 ° CA) Of these, it is determined whether or not it is relatively at the bottom dead center side (step S1103).

  If the air amount is relatively large and it is determined as YES in step S1103, the control unit 2 proceeds to step S1104 and λ (air) with respect to the air amount of the stop-time compression stroke cylinder 12A calculated in step S1102. The fuel is injected so that the air-fuel ratio (excess ratio)> 1 (for example, air-fuel ratio = about 20) (first fuel injection). This air-fuel ratio is obtained from the compression stroke cylinder first-time air-fuel ratio map M1 set in advance according to the stop position of the piston. By setting the lean air-fuel ratio to be λ> 1, even when the air amount in the compression stroke cylinder 12A at the time of stop is relatively large, the combustion energy for the reverse direction does not become excessive, and the reverse rotation is excessive ( In the stop compression stroke cylinder 12A, the piston 13 that has moved to the bottom dead center side passes through the bottom dead center and is prevented from reversing to the intake stroke).

  On the other hand, if the air amount is relatively small and it is determined NO in step S1103, the control unit 2 proceeds to step S1105 and λ ≦ the air amount in the stop-time compression stroke cylinder 12A calculated in step S1102. Fuel is injected so that the air-fuel ratio becomes 1 (first fuel injection: Tf1 in FIG. 15). This air-fuel ratio is obtained from the first-time air-fuel ratio map M2 of the stop-time compression stroke cylinder 12A set in advance according to the stop position of the piston. By setting the stoichiometric air-fuel ratio of λ ≦ 1 or a richer air-fuel ratio, sufficient combustion energy for the reverse direction can be obtained even when the amount of air in the compression stroke cylinder 12A at the time of stop is relatively small. it can.

Next, the control unit 2 proceeds to step S1106, and ignites the cylinder after elapse of a time set in consideration of the vaporization time from the first fuel injection into the stop-time compression stroke cylinder 12A (FIG. 15). Ts1). Then, depending on whether or not the ignition to the crank angle sensor 30, 31 within a predetermined time T _LT from the edge (rising or falling edge of the crank angle signal) is detected, whether the control unit 2 the piston 13 is moved Determination is made (step S1107).

  In step S1107, if it is determined as YES and it is confirmed that the piston 13 has moved, the control unit 2 proceeds to the next step.

On the other hand, if it is determined as NO in step S1107 and it is confirmed that the piston 13 has not moved due to misfire, the control unit 2 determines whether or not the elapsed time T after ignition has elapsed by a predetermined time _TLT . Is determined (step S1108), and if it has not elapsed, reignition is repeatedly performed on the stop-time compression stroke cylinder 12A (step S1109). On the other hand, if the elapsed time T after ignition has passed the predetermined time in step S1108, the control unit 2 proceeds to the assist combined use restart control subroutine S120.

  Referring to FIG. 12 and FIG. 15, when it is determined YES in step S1107 and it is confirmed that the piston 13 has moved, the control unit 2 is based on the piston stop position and the in-cylinder temperature estimated in step S1101. Thus, the split ratio of the split fuel injection to the stop-time expansion stroke cylinder 12B (ratio between the front stage injection (first time) and the rear stage injection (second time)) is calculated (step S1112). The later-stage injection ratio is increased as the piston stop position in the expansion stroke cylinder 12B during the stop is closer to the bottom dead center and the in-cylinder temperature is higher.

  Next, the control unit 2 calculates the fuel injection amount so that a predetermined air-fuel ratio (λ ≦ 1) is obtained with respect to the air amount in the stop-time expansion stroke cylinder 12B calculated in step S1102 (step S1113). The air-fuel ratio at this time is obtained from the expansion stroke cylinder air-fuel ratio map M3 set in advance according to the stop position of the piston. In the present embodiment, correction based on the fuel leak amount is made based on the fuel leak characteristic table M10 in the calculation in step S1112.

  Next, the control unit 2 uses the division ratio calculated in step S1112 and the fuel injection amount to the stop expansion stroke cylinder 12B calculated in step S1113 to perform the first stage for the stop expansion stroke cylinder 12B. The fuel injection amount is calculated and injected (step S1114: Tf2 in FIG. 15).

  Next, the control unit 2 calculates the subsequent (second) fuel injection timing for the stop-time expansion stroke cylinder 12B based on the in-cylinder temperature estimated in step S1101 (step S1115). This second injection timing is a time when the in-cylinder air is compressed after the piston 13 starts moving toward the top dead center (in the reverse direction of the engine), and the vaporization latent heat of the injected fuel is compressed. It is set so that the pressure is effectively reduced (the piston 13 is as close as possible to the top dead center) and the time for the second injected fuel to evaporate by the ignition timing is as long as possible. The

  Next, the control unit 2 calculates the fuel injection amount at the second injection timing calculated in step S1115, and causes the fuel injection valve 16 to inject the calculated amount of fuel (step S1116: Tf3 in FIG. 15). After the second fuel injection to the stop-time expansion stroke cylinder 12B, the control unit 2 drives the spark plug 15 after a predetermined delay time has elapsed (steps S1117 and S1118: Ts2 in FIG. 15). The predetermined delay time is obtained from an expansion stroke cylinder ignition delay map M4 set in advance according to the stop position of the piston. Due to the initial combustion in the expansion stroke cylinder 12B at the time of stop by this ignition, the engine turns from the reverse rotation direction to the normal rotation direction. Therefore, the piston 13 of the stop-time compression stroke cylinder 12A moves to the top dead center side and starts to compress the internal gas (burned gas burned by ignition in step S1106).

After ignition in the stop-state expansion-stroke cylinder 12B in step S1118, the control unit 2, again, the edge of the crank angle sensor 30, 31 from the ignition within a predetermined time T _LT (rising or falling edge of a crank angle signal) It is determined whether or not the piston 13 has moved according to whether or not it has been detected (step S1119). In step S1118, when it is determined as YES and it is confirmed that the piston 13 has moved, the control unit 2 takes fuel vaporization time into consideration and injects fuel into the stop-time compression stroke cylinder 12A (step S1120: FIG. 15). Tf4), the process proceeds to the next step. The fuel injection amount at this time is such that the overall air-fuel ratio based on the total amount with the first injection amount becomes richer (for example, about 6) than the combustible air-fuel ratio (lower limit is 7 to 8). It is obtained from the second air-fuel ratio map M5 for the stop-time compression stroke cylinder 12A set in advance according to the stop position. The compression pressure near the first compression top dead center of the stop-time compression stroke cylinder 12A is reduced by the latent heat of vaporization of the second injection fuel to the stop-time compression stroke cylinder 12A. Can be easily exceeded. Note that the second fuel injection Tf4 to the compression stroke cylinder 12A at the time of stop is performed exclusively for reducing the compression pressure in the cylinder, and ignition and combustion are not performed on this (combustible air-fuel ratio) It ’s richer than that, so there ’s no self-ignition). This incombustible fuel then reacts with oxygen stored in the catalyst 37 in the exhaust passage 22 and is rendered harmless.

On the other hand, if it is determined NO in step S1119 and it is confirmed that the piston 13 has not moved due to misfire, the control unit 2 determines whether or not the elapsed time T after ignition has elapsed by the predetermined time T _LT . Is determined (step S1121), and if not, reignition is repeatedly performed on the compression stroke cylinder 12A at the time of stop (step S1122). Here, in step S1121, when the elapsed time T after ignition has passed a predetermined time, the control unit 2 proceeds to the assist combined use restart control subroutine S120.

  Next, referring to FIGS. 13 and 15, after the fuel injection in step S1120 is completed, the control unit 2 determines whether or not the stop-time compression stroke cylinder 12A passes the top dead center of the compression stroke. (Step S1123). If the addition is not confirmed, it is further determined whether or not a predetermined time has elapsed after the fuel injection (step S1124). If not, the process returns to the determination of step S1123, but the process is stopped even if it has elapsed. When the compression stroke cylinder 12A does not pass the top dead center of the compression stroke, the process proceeds to the assist combined restart control subroutine S120.

  Next, as described above, since the second injected fuel in the stop-time compression stroke cylinder 12A does not burn, the next combustion following the first combustion in the stop-time expansion stroke cylinder 12B is the stop-time intake stroke cylinder 12C. It is burning in. As energy for the piston 13 of the stop-time intake stroke cylinder 12C to exceed the second compression top dead center, a part of the initial combustion energy in the stop-time expansion stroke cylinder 12B is used. That is, the energy of the first combustion in the stop expansion stroke cylinder 12B is that the stop compression stroke cylinder 12A exceeds the first compression top dead center, and then the stop intake stroke cylinder 12C is in the second compression top dead center. For both crossing over and over.

  Therefore, for smooth start-up, it is desirable that the load when the intake stroke cylinder 12C during the stop exceeds the second compression top dead center is small. In that case, the second compression top dead center can be exceeded with small energy. The following flow is control for exceeding the second compression top dead center with as little energy as possible when performing combustion in the next stop intake stroke cylinder 12C.

  First, the control unit 2 estimates the in-cylinder temperature again when the piston 13 of the stop-time compression stroke cylinder 12A passes the compression top dead center (step S1125). The estimation of the in-cylinder temperature is for preventing self-ignition in the stop-time intake stroke cylinder 12C. That is, when self-ignition occurs, a force (reverse torque) is generated that pushes the piston 13 back to the bottom dead center side before reaching the second compression top dead center due to the combustion. This is undesirable because it consumes a lot of energy for exceeding the second compression top dead center. On the other hand, when the stop-time intake stroke cylinder 12C reaches the compression stroke, the engine rotation speed Ne is considerably slow because a part of the initial combustion energy in the stop-time expansion stroke cylinder 12B is allocated. For this reason, the intake-stroke cylinder 12C at the time of stoppage is in a state where self-ignition is likely to occur by introducing relatively high temperature fresh air. Therefore, in this embodiment, when the piston 13 of the compression stroke cylinder 12A at the time of stop passes the compression top dead center, the in-cylinder temperature is estimated again, and self-ignition prevention measures are taken.

  Next, the control unit 2 estimates the in-cylinder air density, and calculates the air amount of the stop-time intake stroke cylinder 12C from the estimated value (step S1126).

Further the control unit 2, based on the air amount estimated in step S1126, calculates a fuel injection amount Q _ST as a reference air-fuel ratio (step S1127). The fuel injection amount _QST is set so that the reference air-fuel ratio is within a range of 10 to 15, that is, a so-called power air-fuel ratio. Thereby, in this embodiment, it becomes possible to obtain a high output by combustion in the stop-time intake stroke cylinder 12C.

Next, the control unit 2 determines whether or not the current time is within a range of about 10 seconds after the engine main body 1 is automatically stopped (step S1128). If it is within this range, the intake air temperature is likely to be extremely high. Therefore, in this embodiment, the additional fuel injection amount FQ _AD for preventing self-ignition is immediately calculated from the estimated value of the in-cylinder temperature. Then, the rich limit is set to 5 or more, and the fuel is injected into the stop-time intake stroke cylinder 12C at an air-fuel ratio richer than the reference air-fuel ratio (step S1129). As a result, even in an operating environment in which the intake air temperature rapidly rises after automatic stop, the calculation of the additional fuel injection amount FQ _AD for preventing self-ignition is performed quickly, and self-ignition can be reliably prevented. It becomes possible.

  Furthermore, when additional injection is executed in step S1129, the multistage injection shown in FIG. 9 is set (see FIG. 15). At that time, referring to the data of the control map M6 based on FIG. 9, the fuel injection amount injected into the subsequent stage is such that the slower the engine speed Ne, the richer the in-cylinder air-fuel ratio is in the combustible range. It is configured to be increased.

  When step S1129 is executed, the fuel injection timing for the cylinder is set to the middle of the compression stroke (step S1130), and then the process proceeds to ignition timing setting step S1141.

  On the other hand, when the elapsed time after the automatic stop is outside the range of about 10 in step S1128, it is determined whether or not self-ignition prevention measures are necessary based on the in-cylinder temperature calculated in step S1125 (step S1131). If the in-cylinder temperature is outside the preset allowable temperature range, the above-described steps after step S1129 are executed.

On the other hand, if it is determined in step S1131 that the in-cylinder temperature is within the preset allowable temperature range, this time, the engine speed at the time when the piston 13 of the stop-time compression stroke cylinder 12A has passed the compression top dead center. Ne is calculated (step S1132), whether or not the calculated engine speed Ne is a predetermined reference rotational speed N _ST or not is determined (step S1133). In this step S1133, if when the engine speed Ne is the reference engine speed N _ST above, the control unit 2, the value of the additional fuel injection amount Q _AD for autoignition prevention and 0 (step S1134). That is, the fuel will not be added to the fuel injection amount Q _ST set in step S1127. On the other hand, if the engine speed Ne is less than the reference engine speed N _ST, the control unit 2 executes the step S1129, to calculate the additional fuel injection amount Q _AD according to the rotational speed, processing proceeds to step S1130 and subsequent steps To do.

Next, referring to FIG. 14, when the additional fuel injection amount Q _AD is calculated in step S1134 or step S1129 described above, this time, the fuel injection amount Q _ST that becomes the reference air-fuel ratio calculated in step S1127. And the additional fuel injection amount Q _AD are added together to calculate the final fuel injection amount FQ (step S1135).

  Next, the control unit 2 shifts to control for determining the fuel injection timing at which the final fuel injection amount FQ is calculated.

  First, it is determined whether or not the cylinder into which this fuel is injected is the first compression stroke of the stop-time intake stroke cylinder 12C (step S1136). If YES, the fuel injection timing is set to the middle of the compression stroke of the cylinder. (About 96 ° CA before compression top dead center) is set (step S1137). On the other hand, if it is a cylinder other than the stop-time intake stroke cylinder 12C, or if it is the second or later fuel injection, it is further determined whether or not the fuel injection in the intake stroke is possible (step S1138). . Here, in the case of the conventional system, when fuel is injected into the cylinders after the intake stroke cylinder 12C at the time of stoppage, it is assumed that the problem of self-ignition cannot occur. I was trying to improve. However, the inventor's research has revealed that self-ignition can occur even in the stop-time exhaust stroke cylinder 12D when the engine speed is relatively low and the intake air temperature is extremely high. Therefore, in the present embodiment, the fuel injection timing is also verified for cylinders that reach compression top dead center after the first compression stroke of the stop-time intake stroke cylinder 12C. Further, as described in the graph of FIG. 9 and step S1129 of FIG. 13, the multi-stage injection is executed within the compression stroke at the timing when the compression stroke is first reached after the restart for the stop-time intake stroke cylinder 12C. (See Tf5 and Tf6 in FIG. 15).

  In step S1138, the same determination as in S1128 to S1133 described above is executed, and it is determined whether the fuel injection timing is in time. If it is determined that there is no possibility of self-ignition from the viewpoint of the engine speed Ne and the in-cylinder temperature, and that it is determined that the fuel can be injected in the intake stroke, the fuel injection timing is set in the intake stroke. (Step S1139) If any of the requirements is not satisfied, the fuel injection timing is retarded in the first half of the compression stroke (Step S1140). Thereby, in the case of a predetermined operation state, the fuel injection timing is set to the intake stroke, and high fuel efficiency and exhaust performance in which vaporization atomization is promoted can be realized, while the operation state in which self-ignition can occur Then, the fuel injection timing is retarded in the compression stroke, so that self-ignition can be surely prevented.

  Next, the control unit 2 delays the ignition timing after the compression top dead center of the cylinder has elapsed (step S1141). This is to prevent the phenomenon that the engine speed Ne suddenly increases when the engine body 1 is restarted transiently.

  The control unit 2 then injects fuel at any of the fuel injection timings determined in steps S1137 to S1139 (step S1142: Tf5 and Tf6 in FIG. 15), and the compression is performed at the ignition timing set in step S1141. After the dead center has elapsed, the spark plug 15 is sparked (step S1143: Ts3 in FIG. 15).

  After this ignition, the control unit 2 waits for a predetermined time until the piston 13 of the target cylinder (here, the intake stroke cylinder 12C at the time of stop) passes the compression top dead center (steps S1144, S1145). If the piston 13 does not pass the compression top dead center even after the predetermined time has elapsed, the control unit 2 proceeds to the assist combined restart control subroutine S120. On the other hand, if the piston 13 exceeds the compression top dead center in step S1144, the control unit 2 sparks the spark plug 15 at the timing set in step S1141 (step S1146: Ts3 in FIG. 15). In this embodiment, since the ignition timing set in step S1141 is delayed after the compression top dead center, it is possible to suppress the occurrence of reverse torque.

  After that, the control unit 2 determines whether or not it is possible to shift to normal operation from the engine speed Ne or the like (step S1144). If possible, the control unit 2 returns to the main routine and performs the normal operation of step S63 shown in FIG. Transition to operation control. In this case, as indicated by Tf9 and Ts6 in FIG. 15, fuel is injected in the intake stroke and ignited before compression top dead center.

  On the other hand, if it is determined that the transition is not possible, the process proceeds to step S1122, so that the determination of whether or not the fuel injection amount and the additional fuel injection amount are appropriate for the cylinder (the exhaust stroke cylinder 12D at the time of stop) that will reach the next compression stroke, The injection timing is determined and the ignition timing is delayed (Tf7, Ts4 in FIG. 15). As a result, it is possible to reliably prevent the self-ignition in the stop-time exhaust stroke cylinder 12D, which has been conventionally overlooked. However, in step S1147, step S1122 is executed again up to the stop exhaust stroke cylinder 12D, and after that, the cylinder that reaches the compression stroke, that is, the second compression of the stop compression stroke cylinder 12A. After the stroke, as shown in FIG. 15, the fuel consumption is improved by injecting fuel during the intake stroke of each cylinder regardless of the engine speed Ne.

As described above, according to the present embodiment, in the reverse rotation start method, the engine body 1 reversely rotated by the combustion in the stop compression stroke cylinder 12A by burning the stop expansion stroke cylinder 12B after the restart. Turns forward. Further, after the burned-down-compression cylinder 12A after burning has passed the first compression stroke, the stopped-intake-stroke cylinder 12C reaches the second compression stroke. In the stop-time intake stroke cylinder 12C, fuel is injected during the compression stroke and ignited at a predetermined timing. Thereafter, for the cylinder that reaches the third compression stroke, the engine speed detected during a predetermined period from the time of combustion in the stop-time expansion stroke cylinder 12B to the time of fuel injection to the stop-time intake stroke cylinder 12C. The fuel injection timing is changed according to Ne. If the detected engine speed Ne is the reference engine rotational speed N _ST or in the predetermined time period, fuel is injected at the latest first half of the compression stroke from the intake stroke first half (see Figure 14). Moreover, if out reference engine rotational speed N _ST more engine rotational speed Ne, it is possible to pass through the second compression top dead center, does not occur self-ignition in the subsequent cylinder before the compression stroke that Therefore, it is possible to improve the output by advancing the fuel injection timing. On the other hand, if it falls below the reference engine rotational speed N _ST, still, the self-ignition in the compression stroke is likely to be caused, in this case, by retarding the fuel injection timing to the middle stage of the compression stroke, the own It is possible to reliably prevent ignition.

  In the present embodiment, the engine body 1 is a four-cylinder engine, and the fuel injection control means determines that the engine rotation speed Ne from the intake stroke after the stop-time intake stroke cylinder 12C has finished the first compression stroke. Regardless of this, fuel is injected during the intake stroke of each cylinder. For this reason, in the present embodiment, after all the cylinders have completed the first compression stroke, paying attention to the fact that they are already in an operating state in which self-ignition is unlikely to occur in the compression stroke, fuel injection is performed during the intake stroke. This makes it possible to improve fuel efficiency.

  Further, in the present embodiment, the control unit 2 has a function capable of estimating the in-cylinder temperature of the engine body 1 until the control unit 2 passes the first compression stroke of the stop-time intake stroke cylinder 12C. When the in-cylinder temperature estimated during this period is equal to or higher than the predetermined temperature, the injection timing is retarded in the middle of the compression stroke regardless of the engine rotational speed Ne. For this reason, in the present embodiment, in the period until the intake stroke cylinder 12C at the time of stoppage shifts to the compression stroke, pay attention to the in-cylinder temperature of the engine body 1, and if the in-cylinder temperature of the engine body 1 is high, the engine Regardless of the rotational speed Ne, the fuel injection timing is retarded in the middle of the compression stroke, thereby preventing more reliable self-ignition.

  In the present embodiment, as shown in FIGS. 5 and 13, it is determined that the in-cylinder temperature is higher as the elapsed time after the automatic stop of the engine body 1 is closer to a predetermined time within 60 seconds. This is based on the knowledge that the air temperature in the cylinder rapidly rises within a predetermined time of 60 seconds or less after the engine body 1 is automatically stopped. Since the operation state detection means is configured to determine that the temperature is high, knocking in a temperature environment in which self-ignition is likely to occur can be reliably prevented.

  Further, in the present embodiment, the ignition plug 15 and the ignition device 27 are provided as ignition control means for executing ignition in each cylinder at a predetermined timing. When the intake stroke cylinder 12C at the time of stoppage first reaches the compression stroke, After the compression top dead center has elapsed, the stop-time compression stroke cylinder 12A is configured to perform ignition. For this reason, in the present embodiment, the ignition in the stop-intake stroke cylinder 12C, which tends to have the highest intake air temperature, is retarded after the compression top dead center has elapsed, so (Rapid increase in the engine speed Ne) can be reliably prevented.

  Further, in this embodiment, as shown by Tf9 and Ts6 in FIG. 15, when the fuel is injected in the compression stroke in the operation state in which the fuel injection in the intake stroke is possible, the ignition timing is set before the compression top dead center. Advance at a predetermined timing. Therefore, in this embodiment, even if there is a sufficient engine speed Ne, if the intake stroke is not in time after the determination timing of the engine speed Ne, fuel injection is executed in the compression stroke. In such a case, since there is little risk of self-ignition, the ignition timing is advanced before the compression top dead center so as to obtain a high output so that both self-ignition prevention and output improvement are achieved. ing.

  Therefore, according to the present embodiment, when the operating state after restart is in an environment where self-ignition is likely to occur, it is possible to take measures that can reliably prevent self-ignition, and thus has not been regarded as a problem so far. There is a remarkable effect that the self-ignition in the cylinder can be surely prevented and the starting reliability can be ensured.

  The above-described embodiments are merely preferred specific examples of the present invention, and the present invention is not limited to the above-described embodiments. It goes without saying that various modifications are possible within the scope of the claims of the present invention.

1 is a schematic configuration diagram of an engine control system according to an embodiment of the present invention. It is a schematic diagram which shows the structure of the intake system and exhaust system of the said engine control system. It is the schematic which shows the suitability of the piston stop range at the time of a stop. It is a schematic diagram which shows the starting procedure of the engine in the said engine control system. It is a flowchart which shows the main flow of restart control. It is a graph which shows the relationship between the stop position of the engine which stopped automatically, and self-ignition generation | occurrence | production timing. 5 is a graph showing the relationship between injection timing and self-ignition for each fuel leak amount in the compression stroke of the intake stroke cylinder when stopped. 5 is a graph showing the relationship between injection timing and self-ignition for each fuel leak amount in the compression stroke of the intake stroke cylinder when stopped. It is a timing chart which shows fuel injection timing. It is a flowchart which shows the main flow of restart control. It is a flowchart which shows a combustion restart control subroutine. It is a flowchart which shows a combustion restart control subroutine. It is a flowchart which shows a combustion restart control subroutine. It is a flowchart which shows a combustion restart control subroutine. It is a timing chart based on the flowchart of FIGS.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Engine body 2 Control unit 3 Crankshaft 12A Stop compression stroke cylinder 12B Stop expansion stroke cylinder 12C Stop intake stroke cylinder 12D Stop exhaust stroke cylinder 13 Piston 14 Combustion chamber 15 Spark plug 16 Fuel injection valve 25 Air flow sensor 26 Suction Atmospheric pressure sensor 27 Ignition device 28 Alternator 29 Intake air temperature sensor 30, 31 Crank angle sensor 32 Cam angle sensor 33 Water temperature sensor 34 Accelerator opening sensor

Claims (6)

When the conditions for restarting a multi-cylinder four-cycle engine that has been automatically stopped are satisfied, the engine is temporarily reversed by a predetermined crank angle by combustion in the compression stroke cylinder at the time of stoppage that was in the compression stroke at the time of stop, and then stopped. In a control device for a multi-cylinder four-cycle engine that causes the engine to normally rotate and restart by combustion in a stop-time expansion stroke cylinder that was sometimes in the expansion stroke,
Electric drive means capable of at least starting assisting the stopped engine;
An operating state detecting means capable of detecting at least the engine speed and the crank position of each cylinder;
Fuel injection control means for controlling the air-fuel ratio of fuel injected into each cylinder and the injection timing based on the rotational speed and crank position detected by the operating state detection means,
The fuel injection control means, when the stop intake stroke cylinder that was in the intake stroke at the time of stop after the restart, first injects the fuel in the compression stroke of the stop intake stroke cylinder, For a cylinder that reaches the compression stroke after the stop intake stroke cylinder, the operating state detection means is provided in a predetermined period from the time of combustion in the stop expansion stroke cylinder to the time of fuel injection into the stop intake stroke cylinder. When the detected engine rotational speed is equal to or higher than a predetermined reference rotational speed, fuel is injected so that the fuel injection timing is delayed as the engine rotational speed is low during the period from the first half of the intake stroke to the first half of the compression stroke, A control device for a multi-cylinder four-cycle engine, characterized in that the fuel is injected in the middle of the compression stroke when it falls below the reference rotational speed. The control device for a multi-cylinder four-cycle engine according to claim 1,
The engine is a four-cylinder engine;
The fuel injection control means is configured to inject fuel at the intake stroke of each cylinder from the intake stroke after the stop-time intake stroke cylinder has finished the first compression stroke, regardless of the engine speed. A control device for a multi-cylinder four-cycle engine characterized by The control device for a multi-cylinder four-cycle engine according to claim 1 or 2,
The operating state detection means has a function capable of estimating the in-cylinder temperature of the engine,
The fuel injection control means adjusts the engine speed when the in-cylinder temperature estimated by the operating state detection means is equal to or higher than a predetermined temperature before the stop-time intake stroke cylinder passes the first compression stroke. A control device for a multi-cylinder four-cycle engine characterized by retarding the injection timing in the middle of the compression stroke. The control device for a multi-cylinder four-cycle engine according to claim 3,
The control device for a multi-cylinder four-cycle engine, wherein the operating state detection means determines that the in-cylinder temperature is higher as the elapsed time after the automatic stop of the engine is closer to a predetermined time within 60 seconds. . The control device for a multi-cylinder four-cycle engine according to any one of claims 1 to 4,
Based on the determination of the operating state determination means, provided with an ignition control means for executing ignition in each cylinder at a predetermined timing,
The ignition control means is configured to execute ignition in the stop-time compression stroke cylinder after the compression top dead center has elapsed when the stop-time intake stroke cylinder first reaches the compression stroke. A control device for a multi-cylinder four-cycle engine. The control apparatus for a multi-cylinder four-cycle engine according to claim 5,
The ignition control means advances the ignition timing to a predetermined timing before the compression top dead center when fuel is injected in the compression stroke in an operation state in which fuel injection in the intake stroke is possible. A control device for a multi-cylinder four-cycle engine.

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