JP3826858B2 - Control device for spark ignition engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a spark ignition engine control device, and more particularly to a device for controlling the combustion state of each cylinder in a multi-cylinder engine to improve fuel consumption and emissions.
[0002]
[Prior art]
Conventionally, in a spark ignition engine, a technique for improving fuel efficiency by performing combustion in a state where the air-fuel ratio of the air-fuel mixture in each cylinder is set to a lean air-fuel ratio larger than the stoichiometric air-fuel ratio is known. As disclosed in Japanese Patent Application Laid-Open No. 10-274085, a fuel injection valve that directly injects fuel into a combustion chamber is provided, and stratified combustion is performed by injecting fuel in the compression stroke from the fuel injection valve in a low-rotation low-load region or the like It is known that the super lean combustion is realized by this.
[0003]
In such an engine, an ordinary three-way catalyst (a catalyst having a high purification performance in the vicinity of the theoretical air-fuel ratio with respect to HC, CO, and NOx) alone as an exhaust gas purification catalyst is sufficient for NOx during lean operation. Since the purification performance cannot be obtained, a lean NOx catalyst that adsorbs NOx in an oxygen-excess atmosphere and removes and reduces NOx in an oxygen-concentrated atmosphere is provided, as shown in the above publication. When such a lean NOx catalyst is used, if the NOx adsorption amount of the lean NOx catalyst increases during the lean operation, for example, as shown in the above publication, additional fuel is injected during the expansion stroke in addition to the main combustion. As a result, the air-fuel ratio of the exhaust gas is enriched and CO is generated, thereby promoting NOx separation and reduction.
[0004]
[Problems to be solved by the invention]
The engine that performs the conventional lean operation as described above requires the lean NOx catalyst in order to ensure the NOx purification performance during the lean operation. A three-way catalyst is also required for exhaust purification in a region operated at a stoichiometric air-fuel ratio such as a high load region, and the lean NOx catalyst is provided in addition to the three-way catalyst, and the lean A NOx catalyst requires a relatively large capacity in order to secure a certain amount of NOx adsorption, and is expensive compared to a three-way catalyst, which is disadvantageous in terms of cost.
[0005]
In addition, in order to maintain the purification performance of the lean NOx catalyst, as described above, the NOx is removed temporarily, temporarily supplied by supplying additional fuel for reduction, etc., every predetermined period when the NOx adsorption amount increases. It is necessary to enrich the air-fuel ratio, which reduces the fuel efficiency improvement effect due to lean combustion.
[0006]
Therefore, in view of such a problem, the applicant of the present application, in a multi-cylinder engine that performs a cycle including intake, compression, expansion, and exhaust strokes, between a pair of cylinders in which an exhaust stroke and an intake stroke overlap in a low load low rotation range. In this case, the burned gas discharged from the preceding cylinder, which is the cylinder on the exhaust stroke side, is directly introduced into the subsequent cylinder, which is the cylinder on the intake stroke side, and the gas discharged from the subsequent cylinder is introduced into the exhaust passage provided with the three-way catalyst. In addition, when the two cylinders are connected, combustion is performed in a state where the preceding cylinder has a lean air-fuel ratio larger than the stoichiometric air-fuel ratio by a predetermined amount, and in the succeeding cylinder, the lean introduced from the preceding cylinder is performed. While controlling the combustion state etc. so that combustion is performed in a state where the stoichiometric air-fuel ratio is supplied by supplying fuel to the burned gas of the air-fuel ratio (referred to as a special operation mode), in the high load high rotation range Usual, I thought to control the combustion conditions or the like so as to perform the combusting respective cylinders at the stoichiometric air-fuel ratio (referred to the normal operation mode) (Japanese Patent Application No. 2002-024548).
[0007]
According to this, by setting the special operation mode in the low-load and low-rotation region, the preceding cylinder is burned at a lean air-fuel ratio, and the thermal efficiency is increased and the pumping loss is reduced, thereby significantly improving the fuel efficiency. Further, in the succeeding cylinder, fuel is supplied to the burned gas having a lean air-fuel ratio introduced from the preceding cylinder, and combustion is performed in a state where the stoichiometric air-fuel ratio is set, and the fuel efficiency effect by reducing the pumping loss is obtained. can get. Moreover, since only the stoichiometric burned gas discharged from the subsequent cylinders is guided to the exhaust passage provided with the three-way catalyst, sufficient exhaust purification performance is ensured with only the three-way catalyst, and no lean NOx catalyst is required. Become.
[0008]
By the way, when the combustion state of each cylinder is controlled as described above, the response of the intake air amount at the time of transition from the high load rotation range to the low load rotation range (when switching from the normal operation mode to the special operation mode). There is a possibility that a delay will occur. For this reason, simply switching to the special operation mode may cause a torque shock (a state in which the torque temporarily decreases) due to this response delay, giving the passenger a sense of incongruity. . That is, when shifting from the normal operation mode to the special operation mode, the throttle valve opening (throttle opening) is controlled so as to introduce a large amount of intake air including the intake air amount of the subsequent cylinder into the preceding cylinder. . However, it is considered that a response delay occurs in the opening degree adjustment, and intake of an amount less than the target intake amount is temporarily performed, and combustion is performed in a state where the stoichiometric air-fuel ratio is set based on this intake amount. As a result, it is conceivable that the torque temporarily decreases.
[0009]
The present invention has been made in consideration of the above-mentioned problems, and improves exhaust gas purification performance by using a three-way catalyst without the need for a lean NOx catalyst while providing fuel efficiency improvement effect by lean combustion. The present invention also provides a control device for a spark ignition engine that can prevent a passenger from feeling uncomfortable due to a torque shock.
[0010]
[Means for Solving the Problems]
According to the first aspect of the invention, the cylinder independent state in which fresh air is introduced into each cylinder and the exhaust gas of the preceding cylinder between the pair of cylinders in which the exhaust stroke and the intake stroke overlap with each other via the inter-cylinder gas passage A normal operation mode in which the flow paths of intake and exhaust are switchable between the two-cylinder connection state introduced into the cylinder and combustion is performed independently in each cylinder with the flow paths as the cylinder-independent states; Multi-cylinder spark ignition configured to switch the operation mode to a special operation mode in which the burned gas discharged from the preceding cylinder is introduced into the succeeding cylinder in the intake stroke as it is in the two-cylinder connection state and combustion is performed. A mode switching means for switching the operation mode to the normal operation mode or the special operation mode according to the operation state of the engine, and the special engine When in the reverse rotation mode, combustion is performed in a state where the preceding cylinder has a lean air-fuel ratio that is larger than the theoretical air-fuel ratio by a predetermined amount, and in the subsequent cylinder, the burned gas having the lean air-fuel ratio derived from the preceding cylinder is used. While fuel is supplied and combustion is performed at a stoichiometric air-fuel ratio, while in the normal operation mode, combustion is performed in each cylinder so that combustion is performed with the air-fuel ratio in each cylinder being the stoichiometric air-fuel ratio. Air-fuel ratio control means for controlling the air-fuel ratio, and the mode switching means switches to the special operation mode when the engine operating state in the normal operation mode becomes a low load and low speed rotation below a predetermined threshold. In addition to switching, the threshold value is further set to a low load side when the engine deceleration is a slow deceleration of a predetermined value or less.
[0011]
According to the present invention, the combustion control in the special operation mode is executed in the two-cylinder connected state in the low load and low rotation range of the engine, so that the preceding cylinder performs the combustion at the lean air-fuel ratio, and the thermal efficiency is improved. As a result, the pumping loss is reduced and a significant fuel efficiency improvement effect is obtained. In the succeeding cylinder, fuel is supplied to the burned gas having a lean air-fuel ratio introduced from the preceding cylinder to obtain the stoichiometric air-fuel ratio. By performing combustion in the state, at least a fuel consumption effect by reducing pumping loss can be obtained. Further, since only the stoichiometric burned gas discharged from the succeeding cylinder is guided to the exhaust passage, the exhaust purification performance is sufficiently ensured only by the three-way catalyst. On the other hand, in the high load / high rotation operation region, the output performance is ensured by setting the normal operation mode.
[0012]
In addition, a predetermined threshold value is provided to switch between the special operation mode and the normal operation mode. For example, when the engine operating state in the normal operation mode becomes a low load and low speed rotation below the predetermined threshold value. The mode switching means is switched from the normal operation mode to the special operation mode. At this time, the torque shock described above is generated. This torque shock is easy to experience during slow deceleration (engine deceleration is small) and at a relatively high load, and during sudden deceleration (engine deceleration is large). In addition, there is a feature that it is difficult to experience at a relatively low load even during slow deceleration.
[0013]
According to the present invention, the threshold value for switching from the normal operation mode to the special operation mode at the time of slow deceleration is further set to the low load side, so this mode switching is performed at a relatively low load even during sudden deceleration or slow deceleration. At the time, that is, in a driving state where it is difficult to experience torque shock. In this way, even without taking measures such as increasing the fuel supply to increase the torque and alleviating the torque shock, it can be made practically difficult to experience the torque shock, while suppressing an increase in fuel consumption, It is possible to effectively prevent the passenger from feeling uncomfortable due to the torque shock.
[0014]
According to a second aspect of the present invention, in the control device for the spark ignition engine according to the first aspect, the air-fuel ratio control means is a fuel for stopping the supply of fuel at least when the engine operating state is in a predetermined deceleration range. A fuel supply stop mode, and in the fuel supply stop mode, the air-fuel ratio control means stops the fuel supply when the engine operating state is a low load and low speed rotation than the predetermined threshold, and the mode switching means Is characterized in that the distribution path is in the two-cylinder connected state.
[0015]
In this way, in the fuel supply stop mode, when the engine operating state is at a low load and low rotation below a predetermined threshold, the fuel supply is stopped, but the gas flow path is the same as in the special operation mode. Two cylinders are connected. Therefore, when the engine load increases from this state and the fuel supply stop mode is canceled, the special operation mode can be quickly switched by simply restarting the fuel supply without switching the flow path.
[0016]
According to a third aspect of the invention, the cylinder independent state in which fresh air is introduced into each cylinder and the exhaust gas of the preceding cylinder between the pair of cylinders in which the exhaust stroke and the intake stroke overlap with each other via the inter-cylinder gas passage A normal operation mode in which the flow paths of intake and exhaust are switchable between the two-cylinder connection state introduced into the cylinder and combustion is performed independently in each cylinder with the flow paths as the cylinder-independent states; Multi-cylinder spark ignition configured to switch the operation mode to a special operation mode in which the burned gas discharged from the preceding cylinder is introduced into the succeeding cylinder in the intake stroke as it is in the two-cylinder connection state and combustion is performed. A mode switching means for switching the operation mode to the normal operation mode or the special operation mode according to the operation state of the engine, and the special engine When in the reverse rotation mode, combustion is performed in a state where the preceding cylinder has a lean air-fuel ratio that is larger than the theoretical air-fuel ratio by a predetermined amount, and in the subsequent cylinder, the burned gas having the lean air-fuel ratio derived from the preceding cylinder is used. While fuel is supplied and combustion is performed at a stoichiometric air-fuel ratio, while in the normal operation mode, combustion is performed in each cylinder so that combustion is performed with the air-fuel ratio in each cylinder being the stoichiometric air-fuel ratio. Air-fuel ratio control means for controlling the air-fuel ratio, the air-fuel ratio control means, after the switching from the normal operation mode to the special operation mode, the torque generated by the preceding cylinder that first reaches the combustion stroke, The air-fuel ratio of the preceding cylinder is made smaller than twice the stoichiometric air-fuel ratio so that the torque generated by the succeeding cylinder is larger, and the air-fuel ratio of the succeeding cylinder relative to the preceding cylinder is the stoichiometric air-fuel ratio. And performing air-fuel ratio correction control such that.
[0017]
According to the present invention, as in the case of the first aspect, the fuel efficiency improvement effect can be obtained by executing the combustion control in the special operation mode in the low load and low rotation range, and the exhaust gas purification can be sufficiently performed only by the three-way catalyst. Performance is ensured. On the other hand, in the high load / high rotation operation region, the output performance is ensured by setting the normal operation mode.
[0018]
At the time of transition from the normal operation mode to the special operation mode (at the time of switching), the generated torque in the preceding cylinder that first reaches the combustion stroke after the mode switching is changed from the generated torque in the subsequent cylinder by the air-fuel ratio correction control. The air-fuel ratio is corrected so as to increase. Unlike simply enriching the air-fuel ratio, this increases the torque generated by combustion immediately after mode switching while making the exhaust from the subsequent cylinders correspond to combustion by the stoichiometric air-fuel ratio. In other words, sudden torque fluctuations are suppressed by adjusting the distribution of the generated torque. As described above, since the fuel consumption does not increase as a whole, the torque shock can be reduced without increasing the fuel consumption. Further, since the exhaust from the subsequent cylinder becomes a gas having a stoichiometric air-fuel ratio, exhaust purification performance is also ensured.
[0019]
According to a fourth aspect of the present invention, in the control device for the spark ignition type engine according to the third aspect, the air-fuel ratio control means performs the air-fuel ratio correction control at the time of slow deceleration when the engine deceleration is not more than a predetermined value. Features.
[0020]
In this way, the torque shock at the time of slow deceleration can be relieved. Therefore, even if the normal operation mode is switched from the normal operation mode to the special operation mode at the time of slow deceleration and relatively high load at which it is easy to experience torque shock, It is possible to effectively prevent the passenger from feeling uncomfortable.
[0021]
The invention according to claim 5 is the normal operation mode in which fuel is directly injected into the combustion chamber and has one combustion stroke between the intake stroke and the exhaust stroke, and two times between the intake stroke and the exhaust stroke. A spark ignition engine control device configured to be able to switch a combustion cycle to a special operation mode having a combustion stroke, wherein the operation mode is switched to the normal operation mode or the special operation mode according to the operation state of the engine. When in the special operation mode, the combustion is performed in a state where the lean air-fuel ratio is larger than the stoichiometric air-fuel ratio by a predetermined amount in the previous combustion, and in the later combustion, While the fuel is supplied to the burned gas at the fuel ratio to perform the combustion with the stoichiometric air-fuel ratio, the combustion is performed with the air-fuel ratio in each cylinder set to the stoichiometric air-fuel ratio in the normal operation mode. An air-fuel ratio control means for controlling the air-fuel ratio in each cylinder, and the mode switching means is configured such that the engine operating state during the normal operation mode has a low load and low speed rotation below a predetermined threshold value. The mode is sometimes switched to the special operation mode, and the threshold value is further set to a low load side at the time of slow deceleration with the engine deceleration being a predetermined value or less.
[0022]
According to the present invention, for example, in the low-load and low-rotation region of the engine, the combustion control in the special operation mode is executed, that is, after the air necessary for the two combustions is supplied, And the subsequent combustion at the stoichiometric air-fuel ratio increase the thermal efficiency and reduce the pumping loss. As a result, a significant fuel efficiency improvement effect can be obtained. In addition, since the air-fuel ratio in the combustion stroke in each cylinder is controlled so that the oxygen concentration of the burned gas becomes a value corresponding to the combustion state of a substantially stoichiometric air-fuel ratio, exhaust purification performance can be sufficiently achieved with only a three-way catalyst. Secured. On the other hand, in the high load / high rotation operation region, the output performance is ensured by setting the normal operation mode.
[0023]
As in the case of claim 1, a predetermined threshold value is provided for switching between the special operation mode and the normal operation mode, and the threshold value for switching from the normal operation mode to the special operation mode at the time of slow deceleration is determined from the rapid deceleration. Since this is set to the low load side, switching of this mode is performed in a driving state in which it is difficult to experience a torque shock. Thus, it is possible to effectively prevent the passenger from feeling uncomfortable due to the torque shock while suppressing the increase in fuel consumption.
[0024]
According to a sixth aspect of the present invention, in the control device for the spark ignition engine according to the fifth aspect, the air-fuel ratio control means is a fuel for stopping the supply of fuel when at least the engine operating state is in a predetermined deceleration range. The fuel supply stop mode, and in the fuel supply stop mode, the air-fuel ratio control means stops the fuel supply when the engine operating state is a low load and low rotation lower than a predetermined threshold in the previous period, and the mode switching means Has the same supply / exhaust stroke as that in the special operation mode.
[0025]
In this way, in the fuel supply stop mode, when the engine operating state is at a low load and low rotation below a predetermined threshold, the fuel supply is stopped, but the supply / exhaust stroke is the same state as in the special operation mode. It becomes. Therefore, when the engine load increases from this state and the fuel supply stop mode is canceled, the special operation mode can be quickly switched by simply restarting the fuel supply without switching the supply / exhaust stroke.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
[0027]
FIG. 1 shows a schematic configuration of an engine according to an embodiment of the present invention, and FIG. 2 schematically shows a structure of one cylinder of an engine main body and intake / exhaust valves provided for the cylinder. In these drawings, the engine body 1 has a plurality of cylinders, and in the illustrated embodiment, has four cylinders 2A to 2D. A piston 3 is fitted into each of the cylinders 2 </ b> A to 2 </ b> D, and a combustion chamber 4 is formed above the piston 3.
[0028]
A spark plug 7 is provided at the top of the combustion chamber 4 of each cylinder 2 </ b> A to 2 </ b> D, and the plug tip faces the combustion chamber 4. An ignition circuit 8 capable of controlling the ignition timing by electronic control is connected to the spark plug 7.
[0029]
A fuel injection valve 9 that directly injects fuel into the combustion chamber 4 is provided at a side portion of the combustion chamber 4. This fuel injection valve 9 incorporates a needle valve and a solenoid (not shown). When a pulse signal described later is input, the fuel injection valve 9 is driven for a time corresponding to the pulse width at the pulse input timing to open the valve. An amount of fuel corresponding to the valve time is injected. The fuel injection valve 9 is supplied with fuel by a fuel pump (not shown) through a fuel supply passage and the like, and is supplied with fuel higher than the pressure in the combustion chamber during the compression stroke. A system is configured.
[0030]
Further, intake ports 11, 11a, 11b and exhaust ports 12, 12a, 12b are opened to the combustion chambers 4 of the respective cylinders 2A to 2D, and an intake passage 15 and an exhaust passage 20 are connected to these ports. Each port is opened and closed by intake valves 31, 31a, 31b and exhaust valves 32, 32a, 32b.
[0031]
The cylinders 2A to 2D perform a combustion cycle including intake, compression, expansion, and exhaust strokes with a predetermined phase difference. In the case of a four-cylinder engine, the first cylinder from one end in the cylinder row direction 2A, 2nd cylinder 2B, 3rd cylinder 2C, 4th cylinder 2D, as shown in FIG. 5, the cycle is in the order of 1st cylinder 2A, 3rd cylinder 2C, 4th cylinder 2D, 2nd cylinder 2B. The combustion cycle is performed with a phase difference of 180 ° in crank angle. In FIG. 5, EX represents an exhaust stroke, IN represents an intake stroke, F represents fuel injection, and S represents ignition.
[0032]
Between a pair of cylinders in which the exhaust stroke and the intake stroke overlap, a cylinder on the intake stroke side (this specification is referred to as a preceding cylinder) from the cylinder on the exhaust stroke side when the exhaust stroke and the intake stroke overlap (this specification is referred to as a preceding cylinder) The inter-cylinder gas passage 22 is provided so that the burned gas can be directly introduced to the subsequent cylinder). In this embodiment, as shown in FIG. 5, the exhaust stroke (EX) of the first cylinder 2A and the intake stroke (IN) of the second cylinder 2B overlap, and the exhaust stroke (EX) of the fourth cylinder 2D and the third stroke Since the intake stroke (IN) of the cylinder 2C overlaps, the first cylinder 2A and the second cylinder 2B, and the fourth cylinder 2D and the third cylinder 2C form a pair, respectively, and the first cylinder 2A and the fourth cylinder 2D are the preceding cylinder. The second cylinder 2B and the third cylinder 2C are the subsequent cylinders.
[0033]
The intake / exhaust port of each cylinder and the intake passage, exhaust passage, and inter-cylinder gas passage connected to the cylinder are specifically configured as follows.
[0034]
The first cylinder 2A and the fourth cylinder 2D, which are the preceding cylinders, respectively include an intake port 11 for introducing fresh air, and a first exhaust port 12a for sending burned gas (exhaust gas) to the exhaust passage. A second exhaust port 12b for leading the burned gas to the subsequent cylinder is provided. The second cylinder 2B and the third cylinder 2C, which are the subsequent cylinders, respectively, have a first intake port 11a for introducing fresh air and a second intake port for introducing burned gas from the preceding cylinder. 11b and an exhaust port 32 for sending the burned gas to the exhaust passage.
[0035]
In the example shown in FIG. 1, the intake ports 11 in the first and fourth cylinders 2A and 2D and the first intake ports 11a in the second and third cylinders 2B and 2C are two per cylinder, the left half of the combustion chamber. The first exhaust port 12a and the second exhaust port 12b in the first and fourth cylinders 2A and 2D and the second intake port 11b and the exhaust port in the second and third cylinders 2B and 2C are provided in parallel on the part side. 12 are provided in parallel on the right half side of the combustion chamber.
[0036]
The intake port 11 in the first and fourth cylinders 2A and 2D and the first intake port 11a in the second and third cylinders 2B and 2C are connected to the downstream ends of the branch intake passages 16 for each cylinder in the intake passage 15. Yes. In the vicinity of the downstream end of each branch intake passage 16, a multiple throttle valve 17 that is linked to each other via a common shaft is provided. This multiple throttle valve 17 is driven by an actuator 18 in accordance with a control signal, The intake air amount is adjusted. Note that an air flow sensor 19 that detects an intake air flow rate is provided in a common intake passage upstream of the collecting portion in the intake passage 15.
[0037]
An upstream end of a branch exhaust passage 21 for each cylinder in the exhaust passage 20 is connected to the first exhaust port 12a in the first and fourth cylinders 2A and 2D and the exhaust port 12 in the second and third cylinders 2B and 2C. Yes. Further, an inter-cylinder gas passage 22 is provided between the first cylinder 2A and the second cylinder 2B and between the third cylinder 2C and the fourth cylinder 2D, respectively, and the first and fourth cylinders which are the preceding cylinders. The upstream end of the inter-cylinder gas passage 22 is connected to the second exhaust ports 12b of 2A and 2D, and the inter-cylinder gas passage 22 is connected to the second intake ports 11b of the second and third cylinders 2B and 2C as the subsequent cylinders. The downstream end is connected.
[0038]
An exhaust gas concentration detection means for detecting the stoichiometric air-fuel ratio is provided at a downstream portion of the branch exhaust passage 21 in the exhaust passage 20. ₂ A sensor 23 is provided, and a three-way catalyst 24 for exhaust purification is provided in the exhaust passage 20 downstream thereof. As is generally known, the three-way catalyst 24 is highly purified against HC, CO, and NOx when the air-fuel ratio of the exhaust gas is close to the stoichiometric air-fuel ratio (that is, the excess air ratio λ is λ = 1). It is a catalyst showing performance. O ₂ The sensor 23 detects the air-fuel ratio by detecting the oxygen concentration in the exhaust gas, and particularly the λO whose output changes suddenly near the stoichiometric air-fuel ratio. ₂ It is composed of sensors.
[0039]
The inter-cylinder gas passage 22 has a linear O output whose output changes linearly with respect to a change in oxygen concentration in the exhaust gas (change in air-fuel ratio). ₂ A sensor 25 (exhaust gas concentration detection means for detecting a lean air-fuel ratio) is provided.
[0040]
The intake / exhaust valves for opening and closing the intake / exhaust ports of each cylinder and the valve operating mechanism for these valves are as follows. That is, the intake port 11, the first exhaust port 12a and the second exhaust port 12b in the first and fourth cylinders 2A and 2D are provided with the intake valve 31, the first exhaust valve 32a and the second exhaust valve 32b, respectively. A first intake valve 31a, a second intake valve 31b, and an exhaust valve 32 are provided in the first intake port 11a, the second intake port 11b, and the exhaust port 12 in the second and third cylinders 2B, 2C, respectively. These intake / exhaust valves are opened and closed at predetermined timings by the valve mechanisms comprising the camshafts 33, 34, etc. so that the intake stroke and exhaust stroke of each cylinder are performed with the predetermined phase difference as described above. To be driven.
[0041]
Further, among these intake / exhaust valves, the first exhaust valve 32a, the second exhaust valve 32b, the first intake valve 31a, and the second intake valve 31b are switched between an operating state and a stopped state. A valve stop mechanism 35 is provided. The valve stop mechanism 35 has been known in the art and will not be shown in detail. For example, hydraulic oil can be supplied to and discharged from a tappet interposed between the cams of the camshafts 33 and 34 and the valve shaft. When a hydraulic oil is supplied to the hydraulic chamber, the operation of the cam is transmitted to the valve and the valve is opened and closed. When the hydraulic oil is discharged from the hydraulic chamber, the cam operation is not performed. The valve is stopped by not being able to be transmitted to.
[0042]
The first control valve 37 and the second exhaust valve 32b are stopped in the hydraulic oil supply / discharge passage 36 to the valve stop mechanism 35 of the first exhaust valve 32a and the valve stop mechanism 35 of the first intake valve 31a. A second control valve 39 is provided in each of the hydraulic oil supply / discharge passages 38 to the mechanism 35 and the valve stop mechanism 35 of the second intake valve 31b (see FIG. 3).
[0043]
FIG. 3 shows the configuration of the engine drive and control system. In this figure, an ECU (control unit) 40 for engine control composed of a microcomputer or the like is provided with an air flow sensor 19, O ₂ Sensor 23 and linear O ₂ A signal from the sensor 25 is input, and further, a signal from an engine speed sensor 45 for detecting the engine speed in order to determine an operating state, an accelerator position sensor 46 for detecting an accelerator position (depressing amount of an accelerator pedal), and the like are also included. Have been entered. The ECU 40 outputs control signals to the fuel injection valves 9, the actuator 18 of the multiple throttle valve 17, and the first and second control valves 37 and 39.
[0044]
The ECU 40 includes an operation state determination unit 41, a valve stop mechanism 35, a valve stop mechanism control unit 42, an intake air amount control unit 43, a fuel injection control unit 44, a path determination unit 51, and the like as functional components.
[0045]
The operating state discriminating means 41 checks changes in the operating state of the engine (engine speed and engine load) based on signals from the rotational speed sensor 45, the accelerator opening sensor 46, etc., and the operating state is low as shown in FIG. It is determined whether it is in the operation region A on the low load side (including the low load operation region A ′) or the high load side or the high rotation side operation region B, or the engine speed changes. Is determined to be less than a predetermined deceleration. Furthermore, the engine load is a low load corresponding to the accelerator fully closed, or the engine speed is in an operating state exceeding a predetermined speed (except for an extremely low speed range in which the engine may be stopped). It is determined whether the vehicle is in the operation region C. Based on the determination result, any one of the special operation mode, the normal operation mode, and the fuel supply stop mode is selected as the engine operation mode (details of each mode will be described later).
[0046]
Specifically, when the engine operating state is in the operation region A ′ (the rotational speed is r1 or less and the engine load is T2 or less) in FIG. 4 and is not in the operation region C described later (for example, the operation state D3), it is special. The operation mode is selected. The normal operation mode is selected in a state where the engine is in the operation region B (the rotation speed exceeds r1 and the engine load exceeds T1) and is not in the operation region C described later (for example, operation state D1). In the operation region A (the rotation speed is r1 or less, the engine load is T1 or less) and not the operation region A ′ (for example, the operation state D2), the special operation mode is selected in principle, but the operation region B (normally When the operation mode shifts to the operation region A and the engine deceleration is smaller than a predetermined value, the normal operation mode is continued. However, even in such a case, when the operation area A ′ is entered, the operation mode is switched to the special operation mode.
[0047]
The operation region C (the region where the engine speed is r3 or more and less than r4, the engine load is T3 or less, and the region where the engine speed is r4 or more) overlaps with either the operation region A or the operation region B. Yes. In any case, when the operating state of the engine is in the operation region C, the fuel supply stop mode (hereinafter referred to as fuel cut mode) is preferentially selected.
[0048]
The valve stop mechanism control means 42 controls the valve stop mechanisms 35 as follows by controlling the control valves 37 and 39 in accordance with the selected operation mode.
Special operation mode: Stops the first exhaust valve 32a and the first intake valve 31a
The second exhaust valve 32b and the second intake valve 31b are activated.
Normal operation mode: the first exhaust valve 32a and the first intake valve 31a are activated
Stop the second exhaust valve 32b and the second intake valve 31b
Fuel cut mode: Same as special operation mode in operation area A
Operation area B is the same as normal operation mode
[0049]
That is, in the normal operation mode, each cylinder is set in an independent state and combustion is performed for each cylinder. In the special operation mode, the preceding cylinder (No. 1, No. 4 cylinders 2A, 2D) and the subsequent cylinder (No. 2, No. 3 cylinder) are performed. 2B, 2C) are connected to each other via the inter-cylinder gas passage 22, and the burned gas discharged from the preceding cylinder is introduced into the succeeding cylinder in the intake stroke as it is to perform combustion. It has become. Further, in the fuel cut mode, in the region overlapping with the operation region A, the two-cylinder connection state is set as in the special operation mode, and in the region overlapping with the operation region B, each cylinder is set in the independent state as in the normal operation mode (however, In the fuel cut mode, the fuel supply is stopped, and in any case, combustion is not performed). As described above, the operating state determination unit 41, the valve stop mechanism control unit 42, and the like function as a mode switching unit.
[0050]
The intake air amount control means 43 controls the opening degree (throttle opening degree) of the throttle valve 17 by controlling the actuator 18, and obtains the target intake air amount from a map or the like according to the operating state, and the target The throttle opening is controlled according to the intake air amount. In particular, in the special operation mode, excess air in the gas introduced from the preceding cylinder is burned in a state where the intake introduction from the branch intake passage 16 to the subsequent cylinders (second cylinder, second cylinder 2B, 2C) is blocked. As shown, the amount of air necessary to burn the fuel corresponding to two cylinders of the preceding cylinder and the succeeding cylinder is supplied to the preceding cylinder (the first and fourth cylinders 2A, 2D). Adjust the throttle opening.
[0051]
The fuel injection control means 44 controls the fuel injection amount and the injection timing from the fuel injection valve 9 provided in each of the cylinders 2A to 2D in accordance with the operating state of the engine. The control state of the fuel injection is changed depending on which of the fuel cut modes is selected. The fuel injection control means 44 and the operating state determination means 41 constitute the air-fuel ratio control means of the present invention.
[0052]
That is, when the special operation mode is selected, for the preceding cylinders (the first and fourth cylinders 2A and 2D), the air-fuel ratio is a lean air-fuel ratio that is larger than the stoichiometric air-fuel ratio, preferably about the stoichiometric air-fuel ratio. The fuel injection amount is controlled so as to be twice or more, and the injection timing is set so that fuel is injected in the compression stroke to cause stratified combustion. On the other hand, for the subsequent cylinders (second and third cylinders 2B and 2C), the fuel injection amount is set so that the fuel is supplied to the burned gas having a lean air-fuel ratio introduced from the preceding cylinder to obtain the stoichiometric air-fuel ratio. In addition to the control, the injection timing is set so that ignition and combustion are possible in a situation where there is a large amount of burned gas. For example, fuel is injected in the compression stroke to ensure ignitability.
[0053]
The fuel injection amount is controlled by the air flow sensor 19 and the O ₂ This is performed by feedback control based on the output from the sensor 23 or the like. Specifically, the basic injection amount for each cylinder is calculated according to the intake air amount detected by the airflow sensor 19 so that the preceding cylinder has a predetermined lean air-fuel ratio and the succeeding cylinder has a stoichiometric air-fuel ratio. The linear O provided in the inter-cylinder gas passage 22 ₂ Based on the output from the sensor 25, the fuel injection amount for the preceding cylinder is feedback-corrected, and an O provided in the exhaust passage 20 is further corrected. ₂ Based on the output from the sensor 23, the fuel injection amount for the subsequent cylinder is feedback-corrected.
[0054]
Further, when the normal operation mode is selected, the fuel injection amount is controlled so that the air-fuel ratio of each of the cylinders 2A to 2D is equal to or lower than the stoichiometric air-fuel ratio. The air-fuel ratio is set to be richer than the stoichiometric air-fuel ratio in the fully open load and the operation region in the vicinity thereof. In this case, the injection timing is set so that uniform combustion is performed by injecting fuel to each of the cylinders 2A to 2D in the intake stroke.
[0055]
When the fuel cut mode is selected, fuel is not injected and the supply is stopped, so that combustion is not performed.
[0056]
The route discriminating means 51 is generated while the crankshaft of the engine rotates by a certain angle according to the change state of the intake flow rate detected by the airflow sensor 19 and the engine speed detected by the speed sensor 45. The number of times of intake pulsation is detected, and based on this number of times of detection, it is determined whether the flow path of intake and exhaust is in the cylinder independent state or in the two-cylinder connected state. That is, in each cylinder independent state where fresh air is introduced into each of the cylinders 2A to 2D, four intake pulsations occur while the crankshaft of the engine rotates once, whereas only the preceding cylinders 2A and 2D In the two-cylinder connected state in which fresh air is introduced into the engine, only two intake pulsations occur while the crankshaft of the engine makes one revolution. And the like, it is determined whether the intake and exhaust flow paths are in an independent state of each cylinder or in a connected state of two cylinders.
[0057]
The operation of the apparatus according to the first embodiment will be described with reference to FIGS.
[0058]
In the special operation mode, as described above, the first exhaust valve 32a and the first intake valve 31a are stopped, and the second exhaust valve 32b and the second intake valve 31b are set in an activated state. As shown in FIG. 6, the gas flow path is such that the burned gas discharged from the preceding cylinders (first and fourth cylinders) 2A and 2D is directly passed through the inter-cylinder gas passage 22 to the subsequent cylinders (second and third cylinders). The cylinders 2B and 2C are introduced into a two-cylinder connection state in which only burned gas discharged from the succeeding cylinders 2B and 2C is guided to the exhaust passage 20 provided with the three-way catalyst 24.
[0059]
In this state, fresh air is introduced into the preceding cylinders 2A and 2D from the intake passage 15 in the intake stroke (arrow a in FIG. 6), and linear O in the preceding cylinders 2A and 2D. ₂ Fuel is injected in the compression stroke while the fuel injection amount is feedback-controlled so that the air-fuel ratio detected by the sensor 25 becomes a predetermined lean air-fuel ratio, and ignition is performed at a predetermined ignition timing. Stratified combustion is performed (see FIG. 5).
[0060]
Thereafter, burned gas discharged from the preceding cylinders 2A and 2D is introduced into the succeeding cylinders 2B and 2C through the gas passage 22 during a period in which the intake strokes of the preceding cylinders 2A and 2D overlap with the exhaust strokes of the succeeding cylinders 2B and 2C. (The white arrow in FIG. 5 and the arrow b in FIG. 6). In the succeeding cylinders 2B and 2C, the fuel is supplied to the burned gas having the lean air-fuel ratio introduced from the preceding cylinders 2A and 2D so that the stoichiometric air-fuel ratio is obtained. ₂ While the fuel injection amount is controlled based on the output of the sensor 23, fuel is injected at an appropriate timing (for example, a compression stroke), and ignition is performed at a predetermined ignition timing to perform combustion (see FIG. 5). The burned gas after combustion in the succeeding cylinders 2B and 2C is discharged to the exhaust passage 20 provided with the three-way catalyst 24 (arrow c in FIG. 6).
[0061]
Thus, in the preceding cylinders 2A and 2D, the stratified combustion at the lean air-fuel ratio is performed, so that the thermal efficiency is increased and the pumping loss is reduced, and the fuel efficiency is greatly improved by the synergistic effect thereof. Further, in the succeeding cylinders 2B and 2C, fuel is supplied to the burned gas in an excess air state and combustion is performed while being controlled to the stoichiometric air-fuel ratio, so that stratified combustion is performed at a lean air-fuel ratio like the preceding cylinders 2A and 2D. Although the thermal efficiency is somewhat inferior to that in which the fuel consumption is performed, the fuel efficiency improvement effect by reducing the pumping loss can be sufficiently obtained.
[0062]
In addition, the burned gas discharged from the succeeding cylinders 2B and 2C to the exhaust passage 20 has a value corresponding to the stoichiometric air-fuel ratio, so there is no need to provide a lean NOx catalyst as in a conventional lean burn engine, and a three-way catalyst. Exhaust purification performance is sufficiently ensured with only 24. And since there is no need to provide a lean NOx catalyst in this way, there is no need to temporarily enrich the air-fuel ratio for NOx release and reduction when the NOx occlusion amount of the lean NOx catalyst increases, improving fuel economy Can be avoided. Furthermore, the problem of sulfur poisoning of the lean NOx catalyst does not occur.
[0063]
The preceding cylinders 2A and 2D have a lean air-fuel ratio that is approximately twice or more than the stoichiometric air-fuel ratio, so that the amount of NOx generated is relatively small. In the succeeding cylinders 2B and 2C, the preceding cylinders 2A and 2D Since the burned gas is introduced, the state is equivalent to that in which a large amount of EGR is performed, so that the generation of NOx is sufficiently suppressed. This is also advantageous for improving emissions.
[0064]
In addition, the burned gas from the preceding cylinders 2A and 2D is introduced into the succeeding cylinders 2B and 2C through the inter-cylinder gas passage 22, and the heat release amount changes according to the passage length in the inter-cylinder gas passage 22. Therefore, the temperature of the burned gas introduced into the succeeding cylinders 2B and 2C can be adjusted by setting the passage length to an appropriate value. In addition, by adjusting the temperature of the burned gas in this way and appropriately adjusting the fuel injection timing for the subsequent cylinders 2B and 2C, the subsequent cylinders 2B and 2C into which a large amount of burned gas is introduced are also ignited, Good combustibility can be maintained.
[0065]
On the other hand, in the normal operation mode, as described above, the first exhaust valve 32a and the first intake valve 31a are in the operating state, and the second exhaust valve 32b and the second intake valve 31b are in the stopped state. The air and gas flow paths are as shown in FIG. 7, and the intake ports 31 and 31 a and the exhaust ports 12 a and 12 of each cylinder 2 </ b> A to 2 </ b> D are substantially independent, and the intake air of each cylinder 2 </ b> A to 2 </ b> D from the intake passage 15. Fresh air is introduced into the ports 31 and 31a, and burned gas is discharged into the exhaust passage 20 from the exhaust ports 31 and 31a of the cylinders 2A to 2D. In this case, the output air performance is ensured by controlling the intake air amount and the fuel injection amount so that the stoichiometric air-fuel ratio or richer (λ ≦ 1).
[0066]
As described above, the special operation mode and the normal operation mode are switched in principle in the operation area A (excluding the operation area C), and in the operation area B (excluding the operation area C) as a rule. Is selected. However, if the normal operation mode is shifted to the operation region A and the engine deceleration is smaller than a predetermined value, the normal operation mode is continued without switching to the special operation mode. Even in such a case, the mode is switched to the special operation mode when the operation area A ′ is entered. Specifically, the mode is selected according to the flowchart shown in FIG.
[0067]
As shown in FIG. 8, when the mode selection flow starts, it is determined whether or not the engine operating region is in the operating region C by the operating state determining means 41 in step S2. If YES is determined in the step S2, the process shifts to a step S4 and shifts to the fuel cut mode control (see FIG. 9, details will be described later). If it is determined as NO in step S2, the process proceeds to step S10, and further the operation region of the engine is determined. If it is determined in step S10 that the vehicle is in the operation region A, the process proceeds to step S12, and it is further determined whether or not the engine is in the operation region A ′. If it is determined NO in step S12, the engine operating state is that the rotational speed is r1 or less, the engine load exceeds T2, and is T1 or less (for example, operating state D2) as shown in FIG. Means. In that case, the process further proceeds to step S14 in FIG. 8 to determine the current operation mode. If it is determined in step S14 that the operation mode is the normal operation mode, it means that the operation mode A is the normal operation mode. This shows a state where the operation state has shifted from the operation state (for example, the operation state D1) in the operation region B of FIG. 4 and has not yet been switched to the special operation mode. In that case, the process further proceeds to step S16 in FIG. 8 to determine whether or not the engine deceleration exceeds a predetermined value α. If YES is determined in the step S16, the process proceeds to a step S18, the special operation mode is controlled, and the process returns. If it is determined as NO in step S16, it indicates that the engine deceleration is in a slow deceleration state with a predetermined value α or less. In such a case, even if it is the driving | operation area | region A, it does not set to special operation mode, but transfers to step S20, continues control of normal operation mode, and returns. Going back to step S12, if YES is determined, or if it is determined in step S14 that the current state is the special operation mode, the process proceeds to step S18 to control the special operation mode, and the process returns. If it is determined in step S10 that the engine operating region is the operating region B, the process proceeds to step S20, the normal operation mode is controlled, and the process returns.
[0068]
By the way, as shown in FIG. 4, the operation regions A, A ′, B and C are regions partitioned by straight lines of engine speed = r1, r3 or r4 and engine loads = T1, T2 or T3. It is. That is, the engine speeds r1, r3, and r4 and the engine loads T1, T2, and T3 are threshold values for switching the operation mode. In the present embodiment, the threshold regarding the engine load for switching from the normal operation mode to the special operation mode is T2 at the time of slow deceleration, and is T1 higher than T2 except at the time of slow deceleration (however, the special operation mode). The threshold regarding the engine load for switching from the normal operation mode to the normal operation mode is constant at T1).
[0069]
When shifting from the normal operation mode to the special operation mode, a torque shock is generated (see FIG. 11, details will be described later). This torque shock is generated when the vehicle is slowly decelerated (the engine deceleration is small) and is relatively heavy. Sometimes it is easy to experience, and it is difficult to experience at a relatively low load even during sudden deceleration (engine deceleration is large) or slow deceleration. Therefore, when the threshold value for switching from the normal operation mode to the special operation mode at the time of slow deceleration is set to a lower load side than at the time of sudden deceleration as described above, the mode switching is performed in an operation state in which torque shock is difficult to experience. Therefore, even if measures such as increasing the fuel supply to increase the torque and relieve the torque shock are taken, it is practically difficult to experience the torque shock, and the torque shock reduces the increase in fuel consumption. It is possible to effectively prevent the passenger from feeling uncomfortable.
[0070]
FIG. 9 is a flowchart of control in the fuel cut mode. After the start, the operation state is discriminated by the operation state discriminating means 41 in step S30, and if it is determined that it is the operation region A, the process proceeds to step S32, where the two-cylinder connection similar to the special operation mode is established in the distribution path. State. Thereafter, the process proceeds to step S36, where the fuel supply is stopped and the process returns. If it is determined in step S30 that the vehicle is in the operation region B, the process proceeds to step S34, and the flow path is set to each cylinder independent state as in the normal operation mode. Thereafter, the process proceeds to step S36, where the fuel supply is stopped and the process returns.
[0071]
In this case, in the fuel cut mode and in the operation state where the engine operation region overlaps with the operation region A (for example, the operation state D4 in FIG. 4), the fuel supply is stopped, but the circulation The route is in the same 2-cylinder connection state as in the special operation mode. Accordingly, when the engine load increases from this state and the fuel cut mode is canceled (for example, when the operation state D3 is entered), the fuel supply is resumed without switching the flow path by the valve stop mechanism control means 42. You can quickly switch to the special operation mode just by doing.
[0072]
In this embodiment, air-fuel ratio correction control by the fuel injection control means 44 may be added when shifting from the normal operation mode to the special operation mode.
In the air-fuel ratio correction control, when shifting from the normal operation mode to the special operation mode, the torque generated by the preceding cylinder that first reaches the combustion stroke after the transition (after mode switching) is larger than the torque generated by the subsequent cylinder for the preceding cylinder. Thus, the fuel injection amount for each of the cylinders 2A to 2D is set so that the air-fuel ratio of the preceding cylinder is smaller than twice the stoichiometric air-fuel ratio and the air-fuel ratio of the succeeding cylinder with respect to the preceding cylinder becomes the stoichiometric air-fuel ratio. It is something to control.
[0073]
Specifically, for example, as shown in FIG. 10, when the mode switching signal is output at the end of the compression stroke of the fourth cylinder 2D ((1) in the figure), the intake and exhaust valves of the pair of cylinders are thereafter turned on together. The valve stop mechanism control means 42 is switched at the time when the valve is closed. According to the example shown in the figure, the first exhaust valves corresponding to the respective cylinders 2A and 2B when the first cylinder 2A and the second cylinder 2B first reach the compression stroke and the expansion stroke ((2) in the figure), respectively. 32a and the first intake valve 31a are switched to the stopped state, the second exhaust valve 32b and the second intake valve 31b are switched to the operating state, and then the third cylinder 2C and the fourth cylinder 2D are respectively subjected to the compression stroke. At the time of reaching the expansion stroke ((3) in the figure), the first exhaust valve 32a and the first intake valve 31a corresponding to the cylinders 2C and 2D are switched to the stopped state, and the second exhaust valve 32b and the second intake valve are switched. The valve 31b is switched to the operating state. Then, when the completion of switching from the normal operation mode to the special operation mode is determined by the path determination means 51 (in the case of (3) in the figure), the cylinder that first reaches the combustion stroke (the fourth cylinder in this example) 2D), the fuel injection amount (F in the figure) so that the air-fuel ratio becomes λ <2 (λ is the excess air ratio; the same applies hereinafter). ₁ Is controlled). Further, the fuel injection amount (F in the figure) is set so that the combustion of the subsequent cylinder (the third cylinder 2C in this example) with respect to the preceding cylinder is performed at the stoichiometric air-fuel ratio. ₂ Is controlled). In the special operation mode in which this air-fuel ratio correction control is not performed, F ₁ The excess air ratio is controlled so that λ = 2. ₁ The air-fuel ratio is corrected to the rich side. And that much F ₂ As a result, the fuel injection amount of the fourth cylinder 2D is reduced as compared with the normal special operation mode. ₁ The generated torque due to the combustion of the No. 3 cylinder 2C F ₂ It becomes larger than the generated torque due to combustion.
[0074]
Thus, by controlling the air-fuel ratio of each cylinder 2A to 2D at the time of mode switching, the torque shock (a phenomenon in which the torque temporarily decreases) accompanying the mode switching is effectively mitigated, and the exhaust purification performance is also improved. Will be secured.
[0075]
That is, in the special operation mode, the throttle opening is controlled so as to supply air necessary for combustion of two cylinders, the preceding cylinder and the succeeding cylinder, to the preceding cylinder (the first and fourth cylinders 2A, 2D). Therefore, the throttle opening is opened at the time of transition from the normal operation mode. At this time, the change in the intake air amount (referred to as the intake air amount) of the preceding cylinder due to the response delay in the operation of the throttle valve 17 and the delay in the change in the intake air flow. A response delay as shown in the uppermost part of FIG. On the other hand, the air-fuel ratio after switching to the special operation mode (shown in the second stage in FIG. 11) is controlled so that the excess air ratio λ in the preceding cylinder becomes λ = 2. Therefore, if no countermeasure is taken, the fuel supply amount corresponding to the intake amount in which the response delay has occurred as described above is controlled, and the fuel injection amount in the preceding cylinder immediately after the mode switching is the third stage in FIG. It decreases sharply as shown by the broken line. Along with this, the average torque of all cylinders rapidly decreases as shown by the broken line in the lowermost stage of FIG. (Torque shock occurs). On the other hand, immediately after mode switching, if combustion is performed in the state where the air-fuel ratio is corrected to the rich side (shown by the solid line in the second stage in FIG. 11) for the preceding cylinder that first reaches the combustion stroke as described above, A decrease in the fuel injection amount in the preceding cylinder is suppressed as indicated by the solid line in the third stage of FIG. On the other hand, by increasing the fuel injection amount in the preceding cylinder and correcting it to the rich side, the fuel injection amount is reduced in the subsequent cylinder, resulting in combustion at the stoichiometric air-fuel ratio (four stages in FIG. 11). (Shown with solid eyes). For this reason, the generated torque in the preceding cylinder becomes larger than the generated torque in the succeeding cylinder, and the decrease in the average torque of all the cylinders is suppressed as indicated by the solid line shown in the lowermost stage of FIG. As a result, torque shock is effectively mitigated. Note that, by controlling the combustion injection amount so that the air-fuel ratio in the subsequent cylinder becomes the stoichiometric air-fuel ratio, the exhaust purification performance is also ensured by the three-way catalyst 24 alone.
[0076]
When the torque shock is sufficiently relieved by the air-fuel ratio correction control, the operation region A ′ may be made equal to the operation region A. That is, regardless of the engine deceleration, the special operation mode is always selected in the operation region A other than the operation region C, and the air-fuel ratio is changed when the operation region B shifts from the operation region B to the operation region A during slow deceleration of the engine. Correction control may be performed.
[0077]
Next, a second embodiment of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected about the same component as 1st Embodiment, and the description is abbreviate | omitted.
[0078]
12 and 13 each have a plurality of cylinders 2, a normal operation mode in which fuel is directly injected into each cylinder 2 and combustion is performed once between the intake stroke and the exhaust stroke, and the intake stroke and the exhaust. The combustion cycle is switched according to the operating state of the engine to a special operation mode in which combustion is performed twice during the stroke, and the oxygen concentration of the exhaust gas discharged to the exhaust passage 20 is brought to a combustion state having a substantially stoichiometric air-fuel ratio. The intake air amount introduced into each of the cylinders 2A to 2D in the intake stroke and the fuel injection amount for performing the two combustions are controlled so as to have a corresponding value, and the exhaust passage 20 The control apparatus of the spark ignition type engine by which the three way catalyst 24 is arrange | positioned is shown.
[0079]
A pair of intake ports 11, 11 and exhaust ports 12, 12 open to the combustion chamber 4 of each cylinder 2, and these ports 11, 11, 12, 12 serve as intake valves 31, 31 and exhaust valves 32, 32 is opened and closed. Each cylinder 2 is combusted in a predetermined order with a predetermined phase difference, that is, a phase difference of 180 ° in crank angle.
[0080]
The intake / exhaust valves 31, 32 are configured to be driven by a valve operating mechanism 53, respectively. As shown in FIG. 13, the valve mechanism 53 is slidably disposed in a housing 54 made of a non-magnetic material, and is integrally connected to the intake / exhaust valves 31 and 32. The armature core 55 and a pair of electromagnets 56 and 57 and return springs 58 and 59 disposed at both upper and lower ends in the housing 34 are provided. Then, by energizing the upper electromagnet 56 and attracting the armature core 55 upward, the intake valve 31 and the exhaust valve 32 are opened at predetermined timings, respectively, and the lower electromagnet 57 is energized to energize the armature core. By suctioning 55 downward, each of the intake valve 31 and the exhaust valve 32 is closed at a predetermined timing.
[0081]
An ECU (control unit) 40 for controlling the engine, which includes a microcomputer for controlling the valve mechanism 53 and the like, includes an air flow sensor 19 and an O ₂ A signal from the sensor 23 is input, and further, a signal from an engine speed sensor 45 for detecting the engine speed and an accelerator position sensor 46 for detecting an accelerator position (accelerator pedal depression amount) in order to discriminate the driving state. Have been entered.
[0082]
The ECU 40 controls the operating state determining means 41 for determining the operating state of the engine, the valve opening / closing control means 60 for controlling the opening / closing timing of the intake valve 31 and the exhaust valve 32, and the intake air amount to the combustion chamber 4 of the engine. An intake air amount control means 43 for controlling the fuel, and a fuel injection control means 44 for controlling the fuel injection state.
[0083]
The valve opening / closing control means 60 functions as a mode switching means together with the operation state determination means 41 and the like, and is output to the valve mechanism 53 when the normal operation mode is selected and when the special operation mode is selected. The opening / closing timing of the intake valve 31 and the exhaust valve 32 is controlled as follows by changing the output timing of the control signal.
[0084]
In the normal operation mode, as shown in FIG. 14A, a normal operation mode comprising an intake stroke IN with fuel injection, a compression stroke with ignition S at a later stage, an expansion stroke with combustion, and an exhaust stroke EX. That is, the opening / closing timings of the intake valve 31 and the exhaust valve 32 are set so as to execute general four-cycle combustion control in which uniform combustion is performed once between the intake stroke IN and the exhaust stroke EX. In FIG. 14, T is the top dead center of the piston stroke, and B is the bottom dead center.
[0085]
In the special operation mode, as shown in FIG. 14B, the intake stroke IN (first stroke), the first compression stroke (second stroke) with the fuel injection F and the ignition S in the latter period, and combustion are involved. And a first expansion stroke (third stroke) in which fuel injection F is performed in the latter period, a second compression stroke (fourth stroke) with ignition S in the latter period, and a second expansion stroke (fifth stroke) with combustion, The intake valve 31 and the exhaust valve so as to execute a special operation mode consisting of an exhaust stroke EX (sixth stroke), that is, six-cycle combustion control in which combustion is performed twice between the intake stroke IN and the exhaust stroke EX. 32 open / close timings are set.
[0086]
The intake air amount control means 43 controls the opening degree of the throttle valve 17 (throttle opening degree) by controlling the actuator 18, and obtains a target intake air amount from a map or the like according to the operating state. The throttle opening is controlled according to the target intake air amount. In particular, in the special operation mode executed mainly in the operation region A on the low load / low rotation side, the burned gas concentration of the exhaust gas discharged to the exhaust passage 20 in the exhaust stroke EX after the two combustions is approximately The throttle opening is adjusted so as to be a value corresponding to the stoichiometric air-fuel ratio combustion state. Further, in the normal operation mode executed mainly in the operation region B on the high load / high rotation side, the throttle opening is adjusted so that the air-fuel ratio in the cylinder 2 satisfies λ ≦ 1.
[0087]
The fuel injection control means 44 controls the fuel injection amount and the injection timing from the fuel injection valve 9 provided in each cylinder 2 according to the operating state of the engine, and particularly in the special operation mode and the normal operation mode. The fuel injection control state is changed, and the fuel injection control means 44 and the operation state determination means 41 constitute the air-fuel ratio control means of the present invention.
[0088]
That is, in the special operation mode, as shown in FIG. 14B, the air-fuel ratio is larger than the stoichiometric air-fuel ratio so that the first combustion performed in the first expansion stroke (third stroke) becomes a stratified combustion state. The fuel injection amount of the first compression stroke (second stroke) is set so that the lean air-fuel ratio, preferably approximately twice or more than the theoretical air-fuel ratio, and the timing of the fuel injection F is set. In addition, by supplying fuel into the burned gas having a lean air-fuel ratio generated by the first combustion (third stroke), the second expansion stroke (fifth stroke) is performed for the second time under the theoretical air-fuel ratio condition. The fuel injection amount is controlled so that combustion is performed, and the timing of the fuel injection F is set so that ignition and combustion can be performed in a situation where there is a large amount of burned gas. For example, the first expansion stroke (third stroke) The fuel injection F is performed in the later stage. The fuel injection amount is controlled by the air flow sensor 19 and the O ₂ This is performed by feedback control based on the output from the sensor 23 or the like.
[0089]
In the normal operation mode, the fuel injection amount is controlled so that the air-fuel ratio of each cylinder 2 is equal to or less than the stoichiometric air-fuel ratio. The fuel injection amount is controlled to be richer than the stoichiometric air-fuel ratio in the region.
[0090]
Note that the same control as in the first embodiment is performed with respect to switching between the engine operating state and the operation mode. That is, the special operation mode is selected in a state where the operation state of the engine is not in the operation region A ′ and the operation region C of FIG. In a state where the operation region B is not in the operation region C, the normal operation mode is selected. In the region that is the operation region A and not the operation region A ′, the special operation mode is selected in principle, but when the operation region B is shifted to the operation region A and the engine deceleration is smaller than a predetermined value. The normal operation mode is continued without switching to the special operation mode. However, even in such a case, when the operation area A ′ is entered, the operation mode is switched to the special operation mode. The operation area C overlaps with either the operation area A or the operation area B. In any case, when the engine operating state is in the operation region C, the fuel cut mode is preferentially selected.
[0091]
The path discriminating means 51 and the start time discriminating means 52 are configured in the same manner as the path discriminating means 51 and the start time control means 52 of the embodiment shown in FIG. According to the detection signal output from the intake pulsation detecting means (air flow sensor 19) for detecting the pulsation, it is determined whether the route is in the normal operation mode control state or the special operation mode control state when the engine is started. When it is determined in the means 51 and it is confirmed that the control state of the special operation mode is in accordance with the determination result of the route determining means 51, the first combustion control is performed for the first time at the engine start. Control such as prohibiting ignition of the injected fuel is executed in the start time control means 52.
[0092]
According to the apparatus of the second embodiment as described above, in the special operation mode, the combustion is performed twice between the intake stroke and the exhaust stroke, and the first combustion performed in the first expansion stroke is performed at the lean air-fuel ratio. By being in the stratified combustion state, the thermal efficiency is increased and the pumping loss is reduced, and the fuel efficiency is greatly improved by these synergistic effects. In addition, by supplying fuel to the burned gas in excess air generated by the first combustion and controlling the stoichiometric air-fuel ratio, the second combustion is performed in the second expansion stroke, so that a normal engine Thus, although the thermal efficiency is inferior to that of stratified combustion at a lean air-fuel ratio, a fuel efficiency effect by reducing pumping loss can be obtained.
[0093]
Moreover, since the concentration of burned gas discharged into the exhaust passage 20 in the exhaust stroke after the second combustion is performed becomes a value corresponding to the stoichiometric air-fuel ratio, lean NOx as in a conventional lean burn engine. There is no need to provide a catalyst, and the exhaust purification performance is sufficiently ensured by the three-way catalyst 24 alone. Since there is no need to provide a lean NOx catalyst in this way, there is no need to temporarily enrich the air-fuel ratio for NOx release and reduction when the NOx occlusion amount of the lean NOx catalyst is increased. Reduction in improvement is avoided. Furthermore, the problem of sulfur poisoning of the lean NOx catalyst does not occur.
[0094]
On the other hand, in the normal operation mode, as described above, general four-cycle combustion control that performs one uniform combustion between the intake stroke IN and the exhaust stroke EX is executed, and the air in each cylinder 2A to 2D is empty. Output performance is ensured by controlling the intake air amount and the fuel injection amount so that the fuel ratio becomes λ ≦ 1.
[0095]
When the engine operating state is not in the operation region C, the switching between the special operation mode and the normal operation mode is performed in the operation region A in principle as in the first embodiment. The normal operation mode is selected. However, when the operation region B (normal operation mode) is shifted to the operation region A and the engine deceleration is smaller than a predetermined value, the normal operation mode is continued without switching to the special operation mode. Even in such a case, the mode is switched to the special operation mode when the operation area A ′ is entered. Specifically, the mode is selected according to the flowchart shown in FIG.
[0096]
Similarly to the first embodiment, the engine speeds r1, r3, and r4 and the engine loads T1, T2, and T3 shown in FIG. 4 are threshold values for switching the operation mode. Also in this embodiment, the threshold regarding the engine load for switching from the normal operation mode to the special operation mode is T2 at the time of slow deceleration, and is T1 higher than T2 at times other than the slow deceleration. By controlling in this way, as in the first embodiment, it is possible to switch from the normal operation mode to the special operation mode in an operation state where it is difficult to experience torque shock. Accordingly, it is possible to effectively prevent the passenger from feeling uncomfortable due to the torque shock while suppressing an increase in fuel consumption.
[0097]
Control in the fuel cut mode is the same as in the first embodiment. When in the operation region A (for example, the operation state D4), the fuel supply is stopped, but the supply / exhaust stroke is the same as in the special operation mode. It becomes a state. Therefore, when the engine load increases from this state and the fuel supply stop mode is released (for example, when the operation state D3 is entered), the valve opening / closing control means 60 switches the opening / closing timing of the intake valve 31 and the exhaust valve 32. Without performing this, it is possible to quickly switch to the special operation mode by simply restarting the fuel supply. Similarly, when in the operation region B, the supply of fuel is stopped and the supply / exhaust stroke is set to the same state as in the normal operation mode.
[0098]
In the second embodiment, in the special operation mode, the intake stroke IN, the first compression stroke, the first expansion stroke with combustion, the second compression stroke, the second expansion stroke with combustion, and the exhaust By performing 6-cycle combustion control including the stroke EX, the combustion is performed twice between the intake stroke IN and the exhaust stroke EX (see FIG. 14B). As a modification, as shown in FIG. 14C, the intake stroke IN, the first compression stroke, the first expansion stroke with combustion, the second compression stroke, the second expansion stroke without combustion, By performing 8 cycles of combustion control consisting of 3 compression strokes, 3rd expansion stroke with combustion, and exhaust stroke EX, the combustion is performed twice between the intake stroke and the exhaust stroke. May be.
[0099]
【The invention's effect】
As described above, the control device according to the present invention has exhausted from the preceding cylinder in the exhaust stroke between the normal operation mode in which each cylinder performs combustion independently and the pair of cylinders in which the exhaust stroke and the intake stroke overlap. It is configured to be able to switch to a special operation mode in which the fuel gas is introduced into the subsequent cylinder in the intake stroke as it is to perform combustion. For example, in the low load low rotation operation region, the special operation mode is set, so that the preceding cylinder In this case, combustion is performed at a lean air-fuel ratio, and the thermal efficiency is increased and the pumping loss is reduced, so that a significant fuel efficiency improvement effect is obtained.In the succeeding cylinder, the existing lean air-fuel ratio introduced from the preceding cylinder is obtained. Combustion is performed in a state where the fuel is supplied to the fuel gas and the stoichiometric air-fuel ratio is set, so that at least a fuel efficiency effect by reducing pumping loss can be obtained. . Further, since only the stoichiometric burned gas discharged from the succeeding cylinder is guided to the exhaust passage, the exhaust purification performance is sufficiently ensured only by the three-way catalyst. On the other hand, in the high load / high rotation operation region, the output performance is ensured by setting the normal operation mode. Then, when shifting from the normal operation mode to the special operation mode, the engine operation state is switched to the special operation mode when the engine speed is lower than the predetermined threshold and the engine speed is reduced to a predetermined value. Since the threshold is set to the lower load side at the time of slow deceleration below the value, it is possible to effectively prevent the passenger from feeling uncomfortable due to torque shock while suppressing an increase in fuel consumption. .
[Brief description of the drawings]
FIG. 1 is a schematic plan view of a whole engine equipped with a control device according to the present invention (first embodiment).
FIG. 2 is a schematic cross-sectional view of an engine body and the like.
FIG. 3 is a block diagram of a control system.
FIG. 4 is an explanatory diagram showing an operation region.
FIG. 5 is a diagram showing an exhaust stroke, an intake stroke, a fuel injection timing, an ignition timing, and the like of each cylinder.
FIG. 6 is an explanatory diagram showing a substantial fresh air and gas flow path during low load and low rotation.
FIG. 7 is an explanatory diagram showing a substantial fresh air and gas flow path when in an operation region on a high load, high and low rotation side.
FIG. 8 is a flowchart for selecting a special operation mode, a normal operation mode, and a fuel cut mode.
FIG. 9 is a flowchart of control in a fuel cut mode.
FIG. 10 is a diagram illustrating an exhaust stroke, an intake stroke, a fuel injection timing, an ignition timing, and the like of each cylinder when transitioning from a normal operation mode to a special operation mode.
FIG. 11 is a diagram showing changes in the intake air amount, air-fuel ratio, fuel injection amount, and generated torque when transitioning from the normal operation mode to the special operation mode.
FIG. 12 is a schematic plan view of a whole engine equipped with a control device according to the present invention (second embodiment).
FIG. 13 is a diagram showing a configuration of a valve operating mechanism and a block configuration of a control system in a second embodiment.
FIG. 14 is an explanatory diagram showing a cylinder combustion cycle, fuel injection timing, ignition timing, and the like in the second embodiment.
[Explanation of symbols]
1 Engine body
2A to 2D cylinder
9 Fuel injection valve
11 Intake port
11a First intake port
11b Second intake port
12 Exhaust port
12a First exhaust port
12b Second exhaust port
15 Intake passage
20 Exhaust passage
22 Inter-cylinder gas passage
24 Three-way catalyst
31 Intake valve
31a First intake valve
31b Second intake valve
32 Exhaust valve
32a First exhaust valve
32b Second exhaust valve
35 Valve stop mechanism
40 ECU
41 Operating state discriminating means
42 Valve stop mechanism control means
43 Intake air amount control means
44 Fuel injection control means
51 Route discrimination means

Claims (6)

Each cylinder independent state in which fresh air is introduced into each cylinder, and a two-cylinder connection state in which exhaust gas of the preceding cylinder is introduced into the succeeding cylinder via the inter-cylinder gas passage between a pair of cylinders in which the exhaust stroke and the intake stroke overlap. The intake and exhaust flow paths are configured to be switchable, and the normal operation mode in which combustion is performed independently in each cylinder with the flow paths set as the cylinder independent state, and the preceding cylinder as the two-cylinder connected state. A multi-cylinder spark ignition engine control device configured to be able to switch the operation mode to a special operation mode in which burned gas discharged from the engine is directly introduced into a subsequent cylinder in the intake stroke to perform combustion. ,
Mode switching means for switching the operation mode to the normal operation mode or the special operation mode according to the operation state of the engine;
In the special operation mode, combustion is performed in a state where the preceding cylinder has a lean air-fuel ratio that is a predetermined amount larger than the stoichiometric air-fuel ratio, and in the succeeding cylinder, the lean air-fuel ratio burned out from the preceding cylinder is burned. While the fuel is supplied to the gas and combustion is performed in a state where the stoichiometric air-fuel ratio is achieved, each cylinder is configured to perform combustion while the air-fuel ratio in each cylinder is set to the stoichiometric air-fuel ratio when in the normal operation mode. Air-fuel ratio control means for controlling the air-fuel ratio at
The mode switching means is for switching to the special operation mode when the engine operating state in the normal operation mode becomes a low load and low speed rotation below a predetermined threshold, and the engine deceleration is a predetermined value. The spark ignition type engine control apparatus, wherein the threshold value is set to a lower load side at the time of slow deceleration below. The air-fuel ratio control means has a fuel supply stop mode for stopping the fuel supply at least when the engine operating state is in a predetermined low load region, and the engine operating state is predetermined in the previous period in the fuel supply stop mode. 2. The air-fuel ratio control means stops the fuel supply when the engine speed is lower than the threshold value, and the mode switching means sets the flow path to the two-cylinder connection state. Spark ignition engine control device. Each cylinder independent state in which fresh air is introduced into each cylinder, and a two-cylinder connection state in which exhaust gas of the preceding cylinder is introduced into the succeeding cylinder via the inter-cylinder gas passage between a pair of cylinders in which the exhaust stroke and the intake stroke overlap. The intake and exhaust flow paths are configured to be switchable, and the normal operation mode in which combustion is performed independently in each cylinder with the flow paths set as the cylinder independent state, and the preceding cylinder as the two-cylinder connected state. A multi-cylinder spark ignition engine control device configured to be able to switch the operation mode to a special operation mode in which burned gas discharged from the engine is directly introduced into a subsequent cylinder in the intake stroke to perform combustion. ,
Mode switching means for switching the operation mode to the normal operation mode or the special operation mode according to the operation state of the engine;
In the special operation mode, combustion is performed in a state where the preceding cylinder has a lean air-fuel ratio that is a predetermined amount larger than the stoichiometric air-fuel ratio, and in the succeeding cylinder, the lean air-fuel ratio burned out from the preceding cylinder is burned. While the fuel is supplied to the gas and combustion is performed in a state where the stoichiometric air-fuel ratio is achieved, each cylinder is configured to perform combustion while the air-fuel ratio in each cylinder is set to the stoichiometric air-fuel ratio when in the normal operation mode. Air-fuel ratio control means for controlling the air-fuel ratio at
The air-fuel ratio control means is configured so that the torque generated by the preceding cylinder that first reaches the combustion stroke after switching from the normal operation mode to the special operation mode is larger than the torque generated by the succeeding cylinder for the preceding cylinder. A spark-ignition engine characterized by performing air-fuel ratio correction control so that the air-fuel ratio of a cylinder is smaller than twice the stoichiometric air-fuel ratio, and the air-fuel ratio of the succeeding cylinder with respect to the preceding cylinder becomes the stoichiometric air-fuel ratio. Control device. 4. The spark ignition engine control apparatus according to claim 3, wherein the air-fuel ratio control means performs the air-fuel ratio correction control at a slow deceleration when the engine deceleration is not more than a predetermined value. A normal operation mode in which fuel is directly injected into the combustion chamber to have one combustion stroke between the intake stroke and the exhaust stroke, and a special operation mode having two combustion strokes between the intake stroke and the exhaust stroke. A spark ignition engine control device configured to be able to switch the combustion cycle to
Mode switching means for switching the operation mode to the normal operation mode or the special operation mode according to the operation state of the engine;
In the special operation mode, combustion is performed in a state where the lean air-fuel ratio is larger by a predetermined amount than the theoretical air-fuel ratio in the previous combustion, and in the subsequent combustion, the lean air-fuel ratio burned by the previous combustion is performed. While the fuel is supplied to the gas and combustion is performed in a state where the stoichiometric air-fuel ratio is achieved, each cylinder is configured to perform combustion while the air-fuel ratio in each cylinder is set to the stoichiometric air-fuel ratio when in the normal operation mode. Air-fuel ratio control means for controlling the air-fuel ratio at
The mode switching means is for switching to the special operation mode when the engine operating state in the normal operation mode becomes a low load and low speed rotation below a predetermined threshold, and the engine deceleration is a predetermined value. The spark ignition type engine control apparatus, wherein the threshold value is set to a lower load side at the time of slow deceleration below. The air-fuel ratio control means has a fuel supply stop mode for stopping the supply of fuel when at least the operating state of the engine is in a predetermined deceleration range,
In the fuel supply stop mode, when the engine operating state is a low load and low speed lower than a predetermined threshold in the previous period, the air-fuel ratio control means stops the fuel supply, and the mode switching means is equivalent to the special operation mode. 6. The spark ignition type engine control device according to claim 5, wherein the supply / exhaust stroke is performed.

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