JP2018071530A - Device and method for controlling engine mounted with supercharger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device and a method for controlling an engine mounted with a supercharger capable of preventing damage to a turbo supercharger by appropriately controlling a rotation speed of a turbine.SOLUTION: When exhaust pressure detected by an exhaust pressure sensor is not less than first predetermined exhaust pressure, a PCM for controlling an amount of fuel supplied to a combustion chamber through a fuel injection valve: sets an upper limit fuel injection amount on the basis of a nozzle opening estimated from a detection result of a nozzle position sensor and an engine rotation speed detected by an engine rotation speed sensor; and executes fuel injection amount limiting control to keep a fuel injection amount per one cycle of the engine not more than the upper limit fuel injection amount.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a control device and a control method for a supercharged engine.

  Conventionally, a turbocharger that supercharges intake air by driving a compressor by rotating the turbine with exhaust gas, and adjusting the cross-sectional area of the exhaust gas in the inlet passage of the exhaust gas to the turbine An engine including a turbocharger having a plurality of movable vanes (movable members) is known (for example, Patent Document 1).

  In the turbocharger described in Patent Document 1, when the supercharging pressure by the compressor is equal to or higher than a first set pressure, a signal for operating the movable vane to the open side so that the supercharging pressure is lowered is provided. When the supercharging pressure by the first supercharging pressure lowering control means to be sent to the actuator of the movable vane and the compressor is equal to or higher than the second set pressure set to a value larger than the first set pressure, The second supercharging pressure lowering control means for sending a signal to the actuator and the supercharging pressure by the compressor so as to operate the movable vane to the opening side larger than the first supercharging pressure lowering control means. Fuel cut control means for stopping the fuel supply to the engine when the pressure is equal to or higher than a third set pressure set to a value larger than the 2 set pressure.

JP 2001-132466 A

  By the way, in the turbocharger having one or a plurality of movable members for adjusting the cross-sectional area of the exhaust gas in the inlet passage to the turbine, it is generated when fuel is burned in the combustion chamber of the engine. When the soot adheres to the movable member, the movable member may adhere to the turbine casing or the like.

  If the movable member is fixed with the flow passage cross-sectional area being reduced, the exhaust energy for rotating the turbine increases, so the turbine speed increases to such a level as to damage the turbocharger itself. Is more likely to do.

  In the turbocharged engine described in Patent Document 1, when the supercharging pressure by the compressor is equal to or higher than the second supercharging pressure, the movable member actuator is operated to open the movable member as far as possible. Even after sending the signal, when the boost pressure does not decrease and exceeds the third boost pressure, it is determined that the movable member is fixed and the fuel supply to the engine is stopped. I try to let them. Thereby, since the exhaust pressure from the engine is suppressed, the turbine rotational speed can be reduced, and damage to the turbocharger can be prevented.

  However, it takes a certain time to determine whether the movable member is fixed. In recent years, turbochargers tend to be miniaturized, and since small turbochargers have a high turbocharge response, the turbocharger is damaged while determining whether the movable member is stuck. There is a risk of it. Therefore, there is room for improvement from the viewpoint of appropriately controlling the rotational speed of the turbine to prevent damage to the turbocharger.

  The present invention has been made in view of such a point, and an object of the present invention is to provide an engine with a supercharger that can appropriately control the rotational speed of the turbine and prevent damage to the turbocharger. The present invention provides a control device and a control method.

  In order to solve the above-described problems, the present invention is directed to a control device for a supercharged engine, and is provided in a fuel injection valve configured to be able to supply fuel into a combustion chamber of the engine and an exhaust passage of the engine. A turbocharger that drives the compressor by rotating the turbine with exhaust gas flowing in the exhaust passage, In the exhaust passage, in the exhaust gas inlet passage to the turbine, a turbocharger having one or more movable members configured to be able to change the cross-sectional area of the exhaust gas, and in the exhaust passage Exhaust pressure detection means for detecting the pressure of the exhaust gas upstream of the turbine, and the exhaust gas passage cross-sectional area in the inlet passage A flow path cross-sectional area detection or estimation means for exiting or estimating, an engine speed detection means for detecting an engine speed from the rotation angle of the output shaft of the engine, and a fuel supplied from the fuel injection valve to the combustion chamber. When the detected exhaust pressure detected by the fuel supply amount control means for controlling the supply amount and the exhaust pressure detection means is equal to or higher than the first predetermined exhaust pressure, it is detected or estimated by the flow path cross-sectional area detection or estimation means. And an upper limit fuel supply amount setting means for setting an upper limit fuel supply amount based on the engine speed detected by the engine speed detection means, and the fuel supply amount control means When the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure, the fuel supply amount per cycle of the engine is set to the upper limit fuel supply amount set by the upper limit fuel supply amount setting means. Is configured to execute the fuel supply amount limiting control for limiting below, was things.

  According to this configuration, the fuel supply amount restriction control is executed when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure without waiting for the determination of whether or not the movable member is in the fixed state.

  That is, since the rotational speed of the turbine basically increases as the exhaust pressure increases, the rotational speed of the turbine damages the turbocharger itself when the exhaust pressure rises above the first predetermined exhaust pressure. Therefore, the fuel supply amount restriction control is executed on the assumption that there is a high possibility that the engine speed increases to such a level (hereinafter, “the turbine is likely to be in an overspeed state”). By this fuel supply amount restriction control, the fuel supply amount can be restricted, and the exhaust pressure in the exhaust upstream side of the turbine in the exhaust passage (hereinafter referred to as the exhaust upstream portion) can be reduced. As a result, the exhaust energy for rotating the turbine is quickly reduced when there is a high possibility that the turbine will be in an overspeed state without waiting for the completion of the determination as to whether or not the movable member is in the fixed state. Thus, the rotational speed of the turbine can be reduced. As a result, it is possible to appropriately control the turbine speed and prevent the turbocharger from being damaged.

  In the control device for an engine with a supercharger, the fuel supply amount control means is configured so that when the detected exhaust pressure is equal to or higher than a second predetermined exhaust pressure set to a value larger than the first predetermined exhaust pressure. In the fuel supply amount restriction control, it is desirable that the fuel supply amount is set to zero.

  That is, for example, if the movable member is fixed at a position where the cross-sectional area of the exhaust gas is minimized, the exhaust pressure in the exhaust upstream portion is reduced to the exhaust pressure at which the turbine is over-rotated. May rise suddenly. At this time, it is desirable to temporarily stop the fuel supply itself to the combustion chamber to reduce the exhaust pressure in the exhaust upstream portion at once. Therefore, when the detected exhaust pressure is equal to or higher than the second predetermined exhaust pressure and the possibility that the turbine will be in an overspeed state is higher, the exhaust pressure in the exhaust upstream portion is rapidly reduced by reducing the fuel supply amount to zero. Can be made. Thereby, damage to the turbocharger can be further prevented.

  In one embodiment of the control device for an engine with a supercharger, the control device further comprises a supercharging pressure detecting means for detecting a supercharging pressure of intake air by the compressor, and the upper limit fuel supply amount setting means is the supercharging pressure detecting means. Is detected or estimated by the flow passage cross-sectional area detection or estimation means even when the detected exhaust pressure is less than the predetermined exhaust pressure. An upper limit fuel supply amount is set based on the flow path cross-sectional area and the engine speed detected by the engine speed detection means, and the fuel supply amount control means includes the boost pressure detection means When the detected supercharging pressure detected by the above is equal to or higher than the predetermined supercharging pressure, the fuel supply amount restriction control is executed even when the detected exhaust pressure is less than the first predetermined exhaust pressure. Structure It is.

  In other words, the higher the turbine speed, the higher the compressor speed, and the higher the exhaust pressure, the higher the exhaust speed, so the fuel supply amount restriction control is executed based on the exhaust pressure. If it does, it can suppress that a turbine will be in an overspeed state. However, since it takes a little time for the exhaust pressure in the exhaust upstream to rise after the movable vane is fixed, for example, the movable member is fixed at a position where the exhaust gas passage sectional area is minimized. In this case, the turbine may be in an overspeed state before the exhaust pressure rises to the first predetermined exhaust pressure.

  Therefore, the fuel supply amount control means executes the fuel supply amount restriction control when the detected supercharging pressure is equal to or higher than the predetermined supercharging pressure, even when the detected exhaust pressure is less than the first predetermined exhaust pressure. To be configured. Since the supercharging pressure basically increases as the compressor speed increases, in addition to the exhaust pressure, the exhaust pressure in the exhaust upstream portion can be reduced by executing the fuel supply amount restriction control based on the supercharging pressure. Even when there is a high possibility that the turbine is in an overspeed state in a state that is not equal to or higher than the first predetermined exhaust pressure, it is possible to prevent the turbocharger from being damaged by suppressing the turbine from being in an overspeed state.

  When the detected exhaust pressure is greater than or equal to the second predetermined exhaust pressure, the supercharged engine control device is configured to reduce the fuel supply amount to 0 in the fuel supply amount restriction control. In one embodiment, the fuel supply amount control means is configured to supply the fuel in the fuel supply amount restriction control when the detected exhaust pressure is not less than the first predetermined exhaust pressure and less than the second predetermined exhaust pressure. When the amount is set based on the detected exhaust pressure, the fuel supply amount is set to be smaller as the detected exhaust pressure is higher than the first predetermined exhaust pressure.

  With this configuration, when the fuel supply amount is set based on the detected exhaust pressure in the fuel supply amount restriction control, the fuel supply amount increases as the detected exhaust pressure is larger than the first predetermined exhaust pressure. Since the exhaust pressure is controlled to be small, the exhaust pressure at the exhaust upstream portion can be quickly reduced even if the exhaust pressure at the exhaust upstream portion is far away from the first predetermined exhaust pressure. . Thereby, damage to the turbocharger can be further prevented.

  Further, another aspect of the present invention is an invention of a control method for an engine with a supercharger. The present invention includes a fuel injection valve configured to be able to supply fuel into a combustion chamber of the engine, and an exhaust passage of the engine. A turbocharger having a turbine provided and a compressor provided in an intake passage of the engine, and driving the compressor by rotating the turbine by exhaust gas flowing in the exhaust passage; A turbocharger having one or a plurality of movable members configured to change a cross-sectional area of the exhaust gas in the exhaust gas inlet passage to the turbine; A method for controlling a turbocharged engine, comprising: an exhaust pressure detection step for detecting a pressure of exhaust gas in a portion of the exhaust passage upstream of the turbine in the exhaust passage; and the inlet A flow passage cross-sectional area detecting or estimating step for detecting or estimating a flow passage cross-sectional area of the exhaust gas, an engine speed detecting step for detecting an engine speed from a rotation angle of the output shaft of the engine, and the fuel When the fuel supply amount setting step for setting the supply amount of fuel supplied from the injection valve to the combustion chamber and the detected exhaust pressure detected in the exhaust pressure detection step are equal to or higher than a first predetermined exhaust pressure, An upper limit fuel supply amount that sets an upper limit fuel supply amount based on the flow path cross-sectional area detected or estimated in the flow path cross-sectional area detection or estimation step and the engine speed detected in the engine speed detection step The fuel supply amount setting step, wherein when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure, the fuel supply amount per cycle of the engine is set to the upper limit fuel supply amount setting step. so A step of setting equal to or less than the upper limit fuel supply flow rate is constant, and a configuration in.

  According to this configuration, when there is a high possibility that the turbine is in an over-rotation state, the fuel supply amount is limited in the fuel supply amount setting step, and the exhaust pressure in the exhaust upstream portion can be quickly reduced. As a result, the exhaust energy for rotating the turbine is quickly reduced when there is a high possibility that the turbine will be in an overspeed state without waiting for the completion of the determination as to whether or not the movable member is in the fixed state. Thus, the rotational speed of the turbine can be reduced. As a result, it is possible to appropriately control the turbine speed and prevent the turbocharger from being damaged.

  In the control method for an engine with a supercharger, the fuel supply amount setting step includes the step of: when the detected exhaust pressure is equal to or higher than a second predetermined exhaust pressure set to a value larger than the first predetermined exhaust pressure. It is desirable that the fuel supply amount be set to zero.

  According to this configuration, when the detected exhaust pressure is equal to or higher than the second predetermined exhaust pressure and the possibility that the turbine is in an overspeed state is higher, by setting the fuel supply amount to 0 in the fuel supply amount setting step, The exhaust pressure in the exhaust upstream portion can be rapidly reduced. Thereby, damage to the turbocharger can be further prevented.

  In one embodiment of the method for controlling the engine with a supercharger, the method further includes a supercharging pressure detection step of detecting a supercharging pressure of intake air by the compressor, and the upper limit fuel supply amount setting step includes the supercharging pressure detection step. When the detected supercharging pressure detected in step S is equal to or higher than the predetermined supercharging pressure, even if the detected exhaust pressure is less than the predetermined exhaust pressure, the detected or estimated channel cross-sectional area and the The upper limit fuel supply amount is set based on the detected engine speed, and the fuel supply amount setting step is performed when the detected boost pressure detected in the boost pressure detection step is equal to or higher than a predetermined boost pressure. In some cases, even when the detected exhaust pressure is less than the first predetermined exhaust pressure, the fuel supply amount per cycle of the engine is set to be equal to or less than the upper limit fuel supply amount.

  That is, since the boost pressure basically increases as the compressor speed increases, in addition to the exhaust pressure, the fuel supply amount per cycle of the engine is less than the upper limit fuel supply amount based on the boost pressure. By limiting the exhaust gas to the turbocharger, even when the exhaust pressure in the exhaust upstream portion is not equal to or higher than the first predetermined exhaust pressure and the turbine is likely to be in the overspeed state, the turbine is prevented from being in the overspeed state. Damage to the turbocharger can be prevented.

  In the method for controlling a supercharged engine, wherein the fuel supply amount setting step is a step of setting the fuel supply amount to 0 when the detected exhaust pressure is equal to or higher than the second predetermined exhaust pressure. The supply amount setting step includes: when the detected amount of fuel is set based on the detected exhaust pressure when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure and less than the second predetermined exhaust pressure. It is desirable that the fuel supply amount be set smaller as the detected exhaust pressure is higher than the first predetermined exhaust pressure.

  With this configuration, when the fuel supply amount is set based on the detected exhaust pressure in the fuel supply amount setting step, the fuel supply amount increases as the detected exhaust pressure is larger than the first predetermined exhaust pressure. Since the exhaust pressure is controlled to be small, the exhaust pressure at the exhaust upstream portion can be quickly reduced even if the exhaust pressure at the exhaust upstream portion is far away from the first predetermined exhaust pressure. . Thereby, damage to the turbocharger can be further prevented.

  As described above, according to the control device and the control method for an engine with a supercharger according to the present invention, when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure regardless of whether the movable member is in the fixed state. In addition, the upper limit fuel supply amount is set based on the flow path cross-sectional area detected or estimated by the flow path cross-sectional area detection or estimation means and the engine speed detected by the engine speed detection means. Since the fuel supply amount per unit is limited to the upper limit fuel supply amount or less, when the turbine rotation speed is likely to increase to a rotation speed that damages the turbocharger itself, the movable member is Without waiting for the determination of whether or not it is in a fixed state, the amount of fuel injection is limited, the exhaust pressure in the exhaust passage upstream of the turbine in the exhaust passage is reduced, and the turbine is quickly The exhaust energy for rolling can be reduced. As a result, it is possible to prevent the turbocharger from being damaged by suppressing the turbine from being over-rotated.

1 is a schematic diagram showing an engine system to which a control device according to an embodiment of the present invention is applied. It is the figure which expanded the turbine chamber of the turbocharger. It is sectional drawing of the turbine chamber cut | disconnected by the III-III line of FIG. It is a block diagram which shows the control system of an engine. It is an example of the map for determining an upper limit fuel injection amount based on an engine speed and a nozzle opening degree. It is a flowchart which shows the processing operation at the time of setting fuel injection quantity based on exhaust pressure and supercharging pressure. 6 is a timing chart showing changes in the fuel injection amount and the exhaust pressure when the detected exhaust pressure becomes an exhaust pressure equal to or higher than a first predetermined exhaust pressure and the fuel injection amount restriction control is executed.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows an engine system 200 to which a control device according to this embodiment is applied. The engine system 200 mainly includes an engine E as a diesel engine, an intake system IN that supplies intake air to the engine E, a fuel supply system FS that supplies fuel to the engine E, and exhaust exhausted from the engine E An exhaust system EX for discharging gas to the outside of the vehicle on which the engine E is mounted, a plurality of sensors for detecting various states relating to the engine system 200, and a powertrain control module 50 (for controlling the engine system 200) 4, hereinafter, the Powertrain Control Module is omitted and is referred to as PCM50).

  The engine E is a multi-cylinder engine having a plurality of cylinders 16a (only one is shown in FIG. 1), and is disposed on the cylinder block 16 provided with the plurality of cylinders 16a. The cylinder head 12 and an oil pan 18 disposed below the cylinder block 16 and storing lubricating oil used for lubricating the drive system of the engine E are provided. A piston 23 is fitted in each cylinder 16a of the engine E so as to be able to reciprocate in the cylinder 16a. A combustion chamber is formed by the top surface of the piston 23, the side wall of the cylinder 16a, and the lower surface of the cylinder head 14. 17 is formed for each cylinder 16a.

  The piston 23 is connected to a crankshaft 25 as an output shaft of the engine E through a connecting rod 24, and the crankshaft 25 is rotated by a reciprocating motion of the piston 23.

  The cylinder head 14 is provided with an intake port 19 and an exhaust port 29 for each cylinder 16a, and an intake valve 15 and an exhaust valve 27 that open and close the opening on the combustion chamber 17 side in the intake port 19 and the exhaust port 29. Are arranged respectively. In addition, the cylinder head 14 is provided with a fuel injection valve 20 configured to be able to supply fuel into the combustion chamber 17 and to improve the ignitability of the mixture of intake air and fuel when the engine E is started. A glow plug 21 is provided for each cylinder 16a.

  Further, the engine system 200 is provided with an alternator 26 that generates electric power using the output of the engine E.

  The engine E includes a cooling water temperature sensor 109 that detects the temperature of cooling water for cooling the engine E and the like, and an engine rotation speed sensor 110 that detects the rotation speed of the engine E from the rotation angle of the crankshaft 25 (engine rotation). Number detecting means) and an optical oil level sensor 111 for detecting the oil level in the oil pan 28 are provided.

  Further, the engine E is configured to be an engine having a relatively small displacement with an displacement of about 1.5 liters. The engine E is relatively small and light, has low mechanical resistance, and has high fuel efficiency.

  The intake system IN has an intake passage 1 communicating with the intake port 19 of each cylinder 16a of the engine E. An air cleaner 3 for filtering the intake air introduced from the outside of the vehicle is disposed at the intake upstream end of the intake passage 1. On the other hand, a surge tank 12 that temporarily stores intake air supplied to the engine E is disposed in the vicinity of the intake downstream side end portion of the intake passage 1. A portion of the intake passage 1 on the intake downstream side of the surge tank 12 is configured by an intake manifold (not shown) that branches for each cylinder 16a, and an end of the intake manifold on the intake downstream side of each cylinder 16a. Each is connected to an intake port 19.

  Between the air cleaner 3 and the surge tank 12 in the intake passage 1, in order from the intake upstream side to the intake downstream side, a connecting portion between the low pressure EGR passage 48a of the low pressure EGR device 48 described later and the intake passage 1, The compressor 5a of the turbocharger 5, the intake shutter valve 7 for adjusting the flow rate of intake air into the combustion chamber 17 of each cylinder 16a, the intercooler 8 that cools the air supercharged by the compressor 5a, and a later-described A connecting portion between the high-pressure EGR passage 43a of the high-pressure EGR device 43 and the intake passage 1 is provided. The intercooler 8 is connected to a water pump 9 that adjusts the flow rate of the cooling water passing through the intercooler 8 via a cooling water passage 10 that is a passage through which the cooling water passes. The cooling water that passes through the intercooler 8 (that is, the cooling water that passes through the cooling water passage 10) is supplied from the engine E.

  In the intake system IN, the intake passage 1 is on the intake downstream side of the air cleaner 3 and the intake upstream side of the compressor 5a (strictly speaking, the intake upstream side of the connection portion between the low pressure EGR passage 48a and the intake passage 1 described later) The air flow sensor 102 for detecting the intake air amount and the first intake air temperature sensor 103 for detecting the temperature of the intake air immediately after passing through the air cleaner 3 are provided in the portion). Further, the intake shutter valve 7 is provided with an intake shutter valve opening sensor 105 for detecting the opening of the intake shutter valve 7, and intake air downstream of the intercooler 8 and intake air from the surge tank 12 in the intake passage 1. A second intake air temperature sensor that detects the temperature of the intake air immediately after passing through the intercooler 8 is provided on the upstream side (strictly speaking, the intake air upstream side of the connection portion between the high pressure EGR passage 43a and the intake passage 1 described later). 106 and a supercharging pressure sensor 107 (supercharging pressure detecting means) for detecting the supercharging pressure of the intake air that has been supercharged by the compressor 5a of the turbocharger 5 and passed through the intercooler 8 are provided. Further, the intake passage 1 is provided with an intake manifold temperature sensor 108 for detecting the temperature of the intake manifold in the intake passage 1.

  The fuel supply system FS includes a fuel tank 30 for storing fuel, and a fuel supply passage 38 for supplying fuel from the fuel tank 30 to the fuel injection valve 20. On the fuel supply passage 38, a low-pressure fuel pump 31, a high-pressure fuel pump 33, and a common rail 35 are provided in this order from the upstream side (fuel tank 30 side). The low pressure fuel pump 31 is provided with a fuel warmer 32, the high pressure fuel pump 33 is provided with a fuel pressure regulator 34, and the common rail 35 is provided with a common rail pressure reducing valve 36. The fuel stored in the fuel tank 30 is sent to the high-pressure fuel pump 33 by the low-pressure fuel pump 31, and the fuel sent to the high-pressure fuel pump 33 is sent to the common rail 35 by the high-pressure fuel pump 33. The common rail 35 can store the pumped fuel at a relatively high fuel pressure. The fuel stored in the common rail 35 is injected into the fuel injection valve 20 when the fuel injection valve 20 is opened. It is injected (supplied) from the mouth into the combustion chamber 17. Although not shown, at least one of a portion between the low pressure fuel pump 31 and the high pressure fuel pump 33 and a portion between the low pressure fuel pump 31 and the high pressure fuel pump 33 in the fuel supply passage 38 is provided. A fuel filter for removing foreign matters and the like contained in the fuel stored in the fuel tank 30 is provided.

  Further, in the fuel supply system FS, a fuel temperature sensor 114 that detects the temperature of the fuel is provided in the high-pressure fuel pump 33, and a fuel pressure sensor 115 that detects the pressure of the fuel in the common rail 35 is provided in the common rail 35. ing.

  The exhaust system EX has an exhaust passage 41 through which exhaust gas passes. The exhaust passage 1 communicates with the exhaust port 29 of each cylinder 16a of the engine E, and the connecting portion between the engine E and the exhaust passage 41 branches for each cylinder 16a and is connected to the outer end of the exhaust port 29. It is constituted by an exhaust manifold (not shown) having an independent passage and a collecting portion where the independent passages gather.

  In the exhaust passage 41, on the exhaust downstream side of the exhaust manifold, in order from the exhaust upstream side, a connecting portion between a high pressure EGR passage 43 a of the high pressure EGR device 43 described later and the exhaust passage 41, and exhaust gas passing through the exhaust passage 41. The turbine 5b of the turbocharger 5 that rotates and rotates the compressor 5a by this rotation, an oxidation catalyst 45 having a function of purifying exhaust gas, and a diesel particulate filter (hereinafter, Diesel particulate filter is abbreviated as DPF). 46), a connecting portion between a low pressure EGR passage 48a and an exhaust passage 41 of a low pressure EGR device 48, which will be described later, and an exhaust shutter valve 49 for adjusting the exhaust flow rate discharged to the outside of the vehicle.

The oxidation catalyst 45 has an oxidation catalyst supporting platinum or platinum added with palladium, etc., and promotes a reaction in which CO and HC in the exhaust gas are oxidized to produce CO ₂ and H ₂ O. It is. The DPF 46 is a filter that collects particulates such as soot in the exhaust gas and purifies the exhaust gas.

In the exhaust system EX, a portion of the exhaust passage 41 on the exhaust upstream side of the turbine 5b (hereinafter referred to as the exhaust upstream portion 41a) has a first exhaust temperature sensor 116 that detects the temperature of the exhaust gas in the exhaust upstream portion 41a. And an exhaust pressure sensor 117 (exhaust pressure detecting means) for detecting the pressure of exhaust gas (hereinafter simply referred to as exhaust pressure) in the exhaust upstream portion 41a. A second exhaust temperature sensor 118 that detects the temperature of the exhaust gas before passing through the oxidation catalyst 45 is provided at a portion of the exhaust passage 41 that is downstream of the turbine 5b and upstream of the oxidation catalyst 45. A third exhaust temperature sensor 119 that detects the temperature of the exhaust gas after passing through the oxidation catalyst 45 and before passing through the DPF 46 is provided in a portion of the exhaust passage 41 between the oxidation catalyst 45 and the DPF 46, The DPF 46 is provided with a DPF differential pressure sensor 120 that detects a difference in exhaust pressure between the exhaust upstream side and the exhaust downstream side of the DPF 46. Further, a portion of the exhaust passage 41 on the exhaust downstream side of the DPF 46 (strictly speaking, an exhaust downstream side of a connection portion between a low pressure EGR passage 48a and an exhaust passage 41 described later) and an exhaust upstream side of the exhaust shutter valve 49 Are provided with a linear O ₂ sensor 121 for detecting the oxygen concentration in the exhaust gas in the portion and a fourth exhaust temperature sensor 122 for detecting the temperature of the exhaust gas in the portion.

  The engine system 200 of the present embodiment further includes a high pressure EGR device 43 and a low pressure EGR device 48 as devices for recirculating a part of the exhaust gas to the intake side. The high-pressure EGR device 43 is a high-pressure EGR that connects a portion between the exhaust manifold and the turbine 5 b of the turbocharger 5 in the exhaust passage 41 and a portion between the intercooler 8 and the surge tank 12 in the intake passage 1. It has a passage 43a and a high-pressure EGR valve 43b that adjusts the flow rate of the exhaust gas that passes through the high-pressure EGR passage 43a, and recirculates the relatively high-pressure exhaust gas discharged to the exhaust passage 41 to the intake side. On the other hand, the low-pressure EGR device 48 connects a portion between the DPF 46 and the exhaust shutter 49 in the exhaust passage 41 and a portion between the air cleaner 3 and the compressor 5 a of the turbocharger 5 in the intake passage 1. A passage 48a, a low-pressure EGR gas cooler 48b for cooling the exhaust gas passing through the low-pressure EGR passage 48a, a low-pressure EGR valve 48c for adjusting the flow rate of the exhaust gas passing through the low-pressure EGR passage 48a, and the low-pressure EGR A low-pressure EGR filter 48d for collecting contaminants such as soot contained in the exhaust gas passing through the passage 48a, and returning the relatively low-pressure exhaust gas discharged to the exhaust passage 41 to the intake side Let

  The turbocharger 5 provided in the engine system 200 of the present embodiment is formed in a small size so that the turbocharging can be performed efficiently even when the turbine 5b rotates at a low speed, and the operation of the engine E is performed. It is configured as a variable capacity turbocharger capable of adjusting the flow rate of the exhaust gas flowing into the turbine 5b by changing the cross-sectional area of the exhaust gas flowing into the turbine 5b according to the state. A movable vane (movable member) 5c for adjusting the flow passage cross-sectional area of the exhaust gas is disposed at the inlet of the turbine 5b, that is, immediately upstream of the turbine 5b in the exhaust passage 41.

  Here, the structure around the turbine 5b of the turbocharger 5 will be described with reference to FIGS.

  As shown in FIGS. 2 and 3, the turbine 5b is disposed at a substantially central portion of a turbine chamber 153a formed in the turbine casing 153, and includes a plurality of movable vanes so as to surround the periphery of the turbine 5b. 5c is arranged. As shown in FIG. 3, each movable vane 5c is rotatably supported by a support shaft 5d that passes through one wall portion of the turbine chamber 153a (the right wall portion of the movable vane 5c in FIG. 3). ing. When the movable vanes 5c are rotated around the support shafts 5d (clockwise in FIG. 2) and inclined so as to be close to each other, they are formed between the movable vanes 5c. Even when the opening degree (nozzle cross-sectional area) of the nozzle 155 is reduced and the exhaust gas flow rate is small, the exhaust energy for rotating the turbine 5b can be increased, so that high supercharging efficiency can be obtained. . On the other hand, when the movable vane 5c rotates to the opposite side (rotates counterclockwise in FIG. 2) and tilts away from each other, the nozzle cross-sectional area increases and the exhaust flow rate increases. Even when there is a lot of air, it is possible to reduce the ventilation resistance and increase the supercharging efficiency. The nozzle cross-sectional area corresponds to the flow path cross-sectional area of the exhaust gas.

  More specifically, as shown in FIG. 3, an annular cavity 153 b is formed inside the turbine casing 153 adjacent to the turbine chamber 153 a in the direction in which the turbine shaft extends so as to correspond to the turbine chamber 153. The support shaft 5d of the movable vane 5c passes through the partition wall between the cavity 153b and the turbine chamber 153a and protrudes into the cavity 153b. A base end portion of a horseshoe-shaped connection member 156 is attached to a portion of the support shaft 5d protruding into the hollow portion 153b, and one end portion of the connection pin 156a is slidable on the distal end side of each connection member 156. Is attached. The other end of the connecting pin 156a is rotatably fixed to a ring member 157 arranged over the entire circumference of the cavity 153b so as to correspond to the movable vane 5c.

  The ring member 157 is drivingly connected to a rod 163 of an actuator 162 (see FIG. 4) via a link mechanism 158. Specifically, as shown in FIG. 3, the link mechanism 158 includes a connection pin 158a whose one end is rotatably connected to the ring member 157, and one end that can be rotated to the other end of the connection pin 158a. The connected first connecting plate member 158b, the columnar member 158c connected to the other end of the first connecting plate member 158b and penetrating the outer wall of the turbine casing 153, and the outside of the turbine casing 153 of the columnar member 158c And a second connecting plate member 158d having one end connected to a protruding end protruding to the other end, and the other end of the second connecting plate member 158d is rotated to the rod 163 of the actuator 162 by a connecting pin 153e. Connected as possible. The rod 162 is operated by the operation of the actuator 162, the operation is transmitted to the ring member 157 through the link mechanism 158, and the ring member 157 rotates around the axis X of the turbine shaft. Each of the movable vanes 5c is synchronously rotated around the support shaft 5d. That is, the opening degree of the nozzle 155 is changed by the operation of the rod 163.

  In the turbocharger 5, a nozzle position sensor 123 that detects the position of the rod 163 is provided in the vicinity of the rod 163.

  The engine system 200 configured as described above is controlled by the PCM 50. The PCM 50 includes a CPU that executes a program, a memory that stores programs and data, a counter timer group, an interface, and a microprocessor that has a path connecting these units.

  As shown in FIG. 4, detection signals from various sensors are input to the PCM 50. Examples of such sensors include a vehicle speed sensor 100 that detects the vehicle speed of the vehicle, an accelerator opening sensor 101 that detects the amount of depression of an accelerator pedal by the driver of the vehicle (accelerator opening by a driver's operation), and an engine E An engine speed sensor 110 that detects the engine speed, a supercharging pressure sensor 107 that detects the supercharging pressure of the intake air that has been supercharged by the compressor 5a of the turbocharger 5 and passed through the intercooler 8, and an exhaust upstream The exhaust pressure sensor 117 that detects the exhaust pressure in the portion 41 a and the nozzle position sensor 123 that detects the position of the rod 163.

  The PCM 50 performs various calculations based on these detection signals to determine the state of the engine E and the vehicle, and in response thereto, various devices (glows) including the actuator 162 that drives the fuel injection valve 20 and the rod 163. Control signals are output to the plug 19 and various valves (the intake shutter valve 7, the exhaust shutter valve 49, the high pressure EGR valve 43b, and the low pressure EGR valve 48c).

  The PCM 50 basically has a fuel injection amount (hereinafter referred to as fuel injection) injected into the combustion chamber 17 per cycle of the engine E based on a torque required by the vehicle driver (hereinafter referred to as required torque). A signal having a pulse width based on the fuel injection amount so that the fuel is injected from the fuel injection valve 20 into the combustion chamber 17 by the set fuel injection amount. 20 is output. The PCM 50 stores a map for determining the fuel injection amount based on the required torque in advance. The PCM 50 sets the fuel injection amount according to the map when setting the fuel injection amount based on the required torque. . Thus, the PCM 50 constitutes a fuel supply amount control means. In the following description, the fuel injection amount set based on the required torque is referred to as a target fuel injection amount. The target fuel injection amount may be increased or decreased with respect to an upper limit fuel injection amount (upper limit fuel supply amount) described later. The required torque is determined based on detection signals from the vehicle speed sensor 100, the accelerator opening sensor 101, and the engine speed sensor 110.

  Further, the PCM 50 estimates the opening degree of the nozzle 155, that is, the flow passage cross-sectional area of the exhaust gas in the inlet passage of the turbine 5b, from the position of the rod 163 detected by the nozzle position sensor 123. That is, the PCM 50 constitutes a channel cross-sectional area estimation unit. A sensor capable of directly detecting the exhaust gas flow passage cross-sectional area may be provided to detect the exhaust gas flow passage cross-sectional area.

  Further, the PCM 50 sets a target nozzle opening based on the detected exhaust pressure detected by the exhaust pressure sensor 117, operates the actuator 162 so that the nozzle opening becomes the target nozzle opening, and moves the rod 163. The nozzle opening degree is adjusted so that the rotational speed of the turbine 5b does not increase to a rotational speed that damages the turbocharger 5 itself while an appropriate supercharging pressure is obtained. In the following description, the “state where the rotational speed has increased to a rotational speed that damages the turbocharger 5 itself” is referred to as an “overspeed state”.

  As described above, by adjusting the nozzle opening, it is possible to raise the boost pressure of the intake air with good responsiveness and to improve the combustion efficiency and to prevent the turbine 5b from being over-rotated. it can. However, when the movable vane 5c does not operate normally, the turbine 5b may be in an overspeed state. That is, as shown in FIG. 3, the clearance between the movable vane 5c and the side wall portion of the turbine chamber 153a is extremely narrow, and soot and the like contained in the exhaust gas are removed from the movable vane 5c and the side wall portion. If it accumulates in the part between, the movable vane 5c will be in the adhering state adhering to the said side wall part. In particular, if the movable vane 5c is stuck in the closed position, the flow rate of the exhaust gas acting on the turbine 5b becomes abnormally high, the turbine 5b is over-rotated, and finally the turbo The turbocharger 5 itself may be damaged.

  As a countermeasure against such sticking of the movable vane 5c, when the exhaust pressure in the exhaust upstream portion 41a is detected and the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure, the movable vane 5c is fixed. After it is determined whether or not the movable vane 5c is in a fixed state, the exhaust upstream portion 41a is reduced by reducing the fuel injection amount into the combustion chamber 17 and reducing the exhaust amount. There is a method in which the exhaust pressure inside the engine is lowered to suppress an increase in the rotational speed of the turbine 5b. However, in the case of a relatively small engine such as the engine E of the present embodiment, the turbocharger 5 is also small, and such a small turbocharger 5 has a high supercharging response, so that it is movable. After the vane 5c is fixed, the turbine 5b may be in an overspeed state while the movable vane 5c is being fixed.

  Therefore, in the present embodiment, the PCM 50 detects the detected engine speed detected by the engine speed sensor 110 and the nozzle position sensor when the detected exhaust pressure detected by the exhaust pressure sensor 117 is equal to or higher than the first predetermined exhaust pressure. The fuel injection amount that limits the fuel injection amount to the upper limit fuel injection amount or less before the upper limit fuel injection amount is set based on the detected nozzle opening detected by 123 and the sticking determination is made. Restriction control (fuel supply amount restriction control) is executed. Here, the first predetermined exhaust pressure is a threshold value for detecting an abnormal increase in exhaust pressure due to a delay in response to the opening side of the movable vane 5c, an increase in the flow rate of exhaust gas exhausted from the engine E, or the like. For example, it is about 400 kPa. The upper limit fuel injection amount is a fuel injection amount that can reduce the exhaust pressure in the exhaust upstream portion 41a to an exhaust pressure smaller than the first predetermined exhaust pressure.

  Hereinafter, the fuel injection amount restriction control executed by the PCM 50 will be specifically described.

  First, the PCM 50 sets the upper limit fuel injection amount based on the detected engine speed and the detected nozzle opening. A map for determining the upper limit fuel injection amount as shown in FIG. 5 is stored in advance in the PCM 50, and the PCM 50 reads the map and sets the upper limit fuel injection amount. That is, the PCM 50 constitutes an upper limit fuel supply amount setting means.

  As shown in FIG. 5, if the detected engine speed is the same, the PCM 50 sets the upper limit fuel injection amount to a smaller value as the detected nozzle opening is smaller. That is, when the nozzle opening is small, the exhaust pressure in the exhaust upstream portion 41a tends to increase, and the exhaust pressure energy for rotating the turbine 5b tends to increase. Therefore, the smaller the detection nozzle opening is, the lower the upper limit fuel injection amount is decreased, the flow rate of the exhaust gas discharged from the engine E to the exhaust passage 41 is decreased, and the exhaust pressure in the exhaust upstream portion 41a is decreased. I have to. In addition, the PCM 50 is configured so that the exhaust gas flow rate is the same as long as the detected nozzle opening is the same except for a region where the engine speed is low enough to prevent the turbine 5b from being over-rotated. The upper limit fuel injection amount is set to a smaller value as the detected engine speed is higher. That is, if the engine speed is high, the flow rate of the exhaust gas discharged from the engine E to the exhaust passage 41 increases, and the exhaust pressure in the exhaust upstream portion 41a tends to increase. For this reason, the upper limit fuel injection amount is decreased, the flow rate of the exhaust gas discharged from the engine E to the exhaust passage 41 is reduced, and the exhaust pressure in the exhaust upstream portion 41a is lowered. Note that the map as shown in FIG. 5 is determined in advance by experiments and can be different for each turbocharger.

After setting the upper limit fuel injection amount, the PCM 50 compares the detected exhaust pressure with the first predetermined exhaust pressure, and based on the magnitude of the detected exhaust pressure with respect to the first predetermined exhaust pressure, the coefficient A _EX To decide. After determining the coefficient A _EX , the PCM 50 multiplies the upper limit fuel injection amount by the coefficient A _EX to obtain a limited fuel injection amount that is a fuel injection amount determined based on the engine speed, the nozzle opening, and the exhaust pressure. calculate.

  Next, the PCM 50 compares the limit fuel injection amount with the target fuel injection amount. When the limit fuel injection amount is equal to or less than the target fuel injection amount, the PCM 50 actually sets the limit fuel injection amount to the combustion chamber. On the other hand, when the limited fuel injection amount is larger than the target fuel injection amount, the target fuel injection amount is set as the final fuel injection amount. To do.

  Then, the PCM 50 operates the fuel injection valve 20 so that the fuel injection amount becomes the set final fuel injection amount. Specifically, a signal having a pulse width such that fuel is injected from the fuel injection valve 20 into the combustion chamber 17 by the final fuel injection amount is output to the fuel injection valve 20.

  As described above, when the detected exhaust pressure is equal to or higher than the predetermined exhaust pressure, the exhaust amount discharged from the engine E to the exhaust passage 41 is reduced by executing the fuel injection amount restriction control. The exhaust pressure in 41a decreases. Thereby, since the exhaust energy for rotating the turbine 5b decreases, the increase in the rotation speed of the turbine 5c is suppressed. As a result, even if the movable vane 5c is fixed in a state where the movable vane 5c is located on the closed side, the turbine 5b can be prevented from being over-rotated, and damage to the turbocharger 5 can be prevented.

  However, for example, if the movable vane 5c is fixed at a position where the nozzle opening is minimized, the exhaust pressure in the exhaust upstream portion 41a suddenly increases to an exhaust pressure at which the turbine 5b enters an overspeed state. May rise. Further, during the execution of the combustion injection amount restriction control, the exhaust pressure in the exhaust upstream portion 41a may rise to an exhaust pressure at which the turbine 5b is in an overspeed state. In these cases, it is desirable to temporarily stop the fuel injection itself into the combustion chamber 17 to reduce the exhaust pressure in the exhaust upstream portion 41a at once.

Therefore, in this embodiment, the PCM 50 sets the final fuel injection amount to 0 when the detected exhaust pressure is equal to or higher than the second predetermined exhaust pressure set to a value higher than the first predetermined exhaust pressure. It is configured. Specifically, the PCM 50 sets the coefficient A _EX to 0 and sets the limit fuel injection amount to 0 when the detected exhaust pressure is equal to or higher than the second predetermined exhaust pressure. When the limit fuel injection amount becomes 0, the final fuel injection amount is set to 0 and the fuel injection is temporarily stopped. Therefore, the flow rate of the exhaust gas from the engine E is sharply reduced and the exhaust gas is exhausted. The exhaust pressure in the upstream portion 41a can be reduced at a stretch. As a result, the exhaust energy for rotating the turbine 5b can be reduced, and the turbine 5b can be prevented from being over-rotated to prevent the turbocharger 5 from being damaged. Here, the second predetermined exhaust pressure is set to a value slightly lower than the exhaust pressure at which the turbine 5b enters an overspeed state, and is set based on the configuration of the turbocharger.

As described above, the coefficient A _EX is set to 0 when the detected exhaust pressure is the second predetermined exhaust pressure. The coefficient A _EX is set to a smaller value as the detected exhaust pressure is higher than the first predetermined exhaust pressure in a range where the detected exhaust pressure is greater than or equal to the first predetermined exhaust pressure and less than the second predetermined exhaust pressure. The Specifically, when the detected exhaust pressure is the first predetermined exhaust pressure, 1 is set to a value closer to 0 as the first predetermined exhaust pressure approaches the second predetermined exhaust pressure. The coefficient A _EX when the detected exhaust pressure is a value between the first predetermined exhaust pressure and the second predetermined exhaust pressure is an exhaust pressure due to the interaction between the engine E and the turbocharger 5. The rise and fall of the turbocharger is determined in advance by experiments, and can be set to a different value for each turbocharger.

  The PCM 50 performs the fuel injection amount restriction control as described above, and simultaneously determines whether or not the movable vane 5c is fixed, and whether or not the movable vane 5c is actually fixed. Judgment is being made. The sticking determination detects whether or not the state where the deviation amount of the detected nozzle opening with respect to the target nozzle opening of the nozzle 155 set based on the detected exhaust pressure is a predetermined value or more continues for a predetermined time or more. By doing. The predetermined time is about 3 seconds.

  Here, since the rotational speed of the turbine 5c increases as the exhaust pressure in the exhaust upstream portion 41a increases, basically, the turbine 5b is excessively controlled by controlling the fuel injection amount based on the detected exhaust pressure. Although the rotation state can be prevented, since it takes a little time for the exhaust pressure in the exhaust upstream portion 41a to rise after the movable vane 5c is fixed, for example, the movable vane 5c When the nozzle is fixed at a position where the nozzle opening is minimized, there is a possibility that the turbine 5b may be over-rotated before the exhaust pressure in the exhaust upstream portion 41a rises to the first predetermined exhaust pressure.

  Therefore, in the present embodiment, the PCM 50 is configured such that when the detected supercharging pressure detected by the supercharging pressure sensor 107 is equal to or higher than the predetermined supercharging pressure, the detected exhaust pressure is less than the predetermined exhaust pressure. The fuel injection amount restriction control is executed.

Specifically, when the detected supercharging pressure is equal to or higher than the predetermined supercharging pressure, the PCM 50 sets an upper limit fuel injection amount based on the detected engine speed and the detected nozzle opening, The detected boost pressure is compared with the predetermined boost pressure to set the coefficient A _BO . Next, the PCM 50 sets the limit fuel injection amount by multiplying the upper limit fuel injection amount by the coefficient A _BO . The PCM 50 compares the limit fuel injection amount with the target fuel injection amount, and sets the final fuel injection amount to the limit fuel injection amount when the limit fuel injection amount is equal to or less than the target fuel injection amount. On the other hand, when the limited fuel injection amount is larger than the target fuel injection amount, the target fuel injection amount is set to the final fuel injection amount. Thereafter, the PCM 50 operates the fuel injection valve 20 so that the fuel injection amount becomes the set final fuel injection amount. The coefficient A _BO is determined in advance by experiments, like the coefficient A _EX, and is set to a smaller value as the detected boost pressure is larger than the predetermined boost pressure. . The coefficient A _BO can be set to a different value for each turbocharger.

  Thereby, even when the detected exhaust pressure is less than the first predetermined exhaust pressure, the detected supercharging pressure may be equal to or higher than the predetermined supercharging pressure, and the turbine 5b may be in an overspeed state. When there is, since the fuel injection amount is limited, it is possible to prevent the turbocharger 5 from being damaged by suppressing the turbine 5b from being over-rotated.

As described above, the fuel injection amount restriction control by the PCM 50 is based on the condition that the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure, and the condition that the detected boost pressure is equal to or higher than the predetermined boost pressure. It is executed when at least one of the conditions is met. When both of the two conditions are satisfied, the PCM 50 can set the coefficient A _EX and the coefficient A _BO based on the detected exhaust pressure and the detected supercharging pressure, respectively, and can further suppress the fuel injection amount. One of the coefficients, that is, the smaller coefficient is selected to calculate the limited fuel injection amount. Conversely, when both of the two conditions are not satisfied, the fuel injection amount restriction control is not executed.

  Next, the processing operation of the PCM 50 when executing the fuel injection amount restriction control will be described based on the flowchart of FIG. In the flowchart described below, at least one of the condition that the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure and the condition that the detected boost pressure is equal to or higher than the predetermined boost pressure is satisfied. It is a flowchart performed after being performed.

  In the first step S101, input signals from various sensors and switches are read, and in the next step S102, the target fuel injection amount is set based on the torque required by the driver.

  In subsequent step S103, an upper limit fuel injection amount is set based on the detected engine speed and the detected nozzle opening.

In the next step S104, the exhaust pressure sensor 117 detects the exhaust pressure in the exhaust upstream portion 41a, and in the next step S105, the coefficient A _EX is set. When the detected exhaust pressure is not equal to or higher than the first predetermined exhaust pressure, the coefficient A _EX is set to infinity.

In step S106, the supercharging pressure sensor 107 detects the supercharging pressure of the intake air from the compressor 5a, and in the next step S107, the coefficient A _BO is set. When the supercharging pressure is not equal to or higher than the predetermined supercharging pressure, the coefficient A _BO is set to infinity.

In the next step S108, the coefficient A _EX is compared with the coefficient A _BO, and the smaller coefficient is selected. As described above, this flowchart shows at least one of the condition that the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure and the condition that the detected boost pressure is equal to or higher than the predetermined boost pressure. because it is being performed after the filled, never both coefficients a _EX and coefficients a _BO is set to infinity, at least one of the coefficients a _EX and coefficients a _BO, 0 or more and 1 The following values are set.

  In step S109, the limited fuel injection amount is calculated by multiplying the upper limit fuel injection amount by the coefficient selected in step S108.

  In the next step S110, the target fuel injection amount is compared with the limit fuel injection amount to determine whether or not the limit fuel injection amount is equal to or less than the target fuel injection amount. When the determination in step S110 is NO, the process proceeds to step S112. When the determination in step S110 is YES, the process proceeds to step S111.

  In step S111, the limited fuel injection amount is set to the final fuel injection amount. After step S111, an output signal (pulse signal) is sent to the fuel injection valve 20 so that fuel is injected by the final fuel injection amount (that is, the limited fuel injection amount), and then the routine returns.

  On the other hand, in step S112, the target fuel injection amount is set to the final fuel injection amount. After step S112, an output signal (pulse signal) is sent to the fuel injection valve 20 so that fuel is injected by the final fuel injection amount (that is, the target fuel injection amount), and then the routine returns.

  While the PCM 50 satisfies at least one of the condition that the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure and the condition that the detected boost pressure is equal to or higher than the predetermined boost pressure, The fuel injection amount restriction control is performed for each cycle of the engine E based on the flowchart.

  Next, changes in the exhaust pressure and the fuel injection amount in the exhaust upstream portion 41a when the fuel injection amount restriction control is executed as described above will be described with reference to FIG. The broken line shown in the exhaust pressure graph represents the first predetermined exhaust pressure. Note that the exhaust pressure shown in FIG. 7 is the detected exhaust pressure detected by the exhaust pressure sensor 117. FIG. 7 shows a timing chart when the detected supercharging pressure is less than the predetermined supercharging pressure in the time range shown in FIG.

  As described above, when the exhaust pressure in the exhaust upstream portion 41a is less than the first predetermined exhaust pressure, the PCM 50 injects fuel at a target fuel injection amount set based on the driver's required torque. For example, when there is an acceleration request from the driver at time t1, the PCM 50 sets the target fuel injection amount so as to increase the fuel injection amount and injects fuel from the fuel injection valve 20 into the combustion chamber 17. Further, when the driver requests acceleration, the engine speed increases. At this time, since the flow rate of the exhaust gas from the engine E to the exhaust upstream portion 41a increases, the PCM 50 operates the actuator 162 so as to increase the nozzle opening degree in order to prevent the turbine 5b from being over-rotated. Let

  Here, when the movable vane 5c enters the fixed state at time t2, the exhaust pressure in the exhaust upstream portion 41a increases. When the exhaust pressure in the exhaust upstream portion 41a (that is, the detected exhaust pressure) becomes equal to or higher than the first predetermined exhaust pressure at time t3, the PCM 50 executes fuel injection amount restriction control based on the flowchart shown in FIG. To do. As a result, the flow rate of the exhaust gas from the engine E to the exhaust upstream portion 41a decreases, so that the exhaust pressure in the exhaust upstream portion 41a gradually decreases even when the movable vane 5c remains in the fixed state. Thereby, the exhaust pressure in the exhaust upstream portion 41a can be made less than the first predetermined exhaust pressure.

  Although not clearly shown in FIG. 7, when the detected exhaust pressure becomes smaller than the first predetermined exhaust pressure, the PCM 50 stops the fuel injection amount restriction control and based on the required torque. A fuel injection amount is set (that is, the target fuel injection amount is set as a final fuel injection amount). When the detected exhaust pressure becomes equal to or higher than the first predetermined exhaust pressure again, the PCM 50 executes the fuel injection amount restriction control again.

  Further, the PCM 50 starts the sticking determination when the exhaust pressure in the exhaust upstream portion 41a becomes equal to or higher than the first predetermined exhaust pressure at time t3. As described above, the sticking determination is performed by detecting whether or not the state where the deviation amount of the detection nozzle opening with respect to the target nozzle opening is a predetermined value or more continues for a predetermined time or more. It takes about a predetermined time (about 3 seconds) from the start of determination to the end of determination. Therefore, the sticking determination ends at time t4 when a predetermined time has elapsed from time t3.

  In the exhaust pressure graph of FIG. 7, a change in the exhaust pressure when the fuel injection amount is limited after the sticking determination is performed without executing the fuel injection amount limitation control is indicated by a one-dot chain line. From the graph of the exhaust pressure in FIG. 7, it can be seen that when the fuel injection amount restriction control is not executed, the exhaust pressure continues to increase while the sticking determination is performed. In this way, if the exhaust pressure continues to rise, the turbine 5b enters an overspeed state, and the turbocharger 5 is likely to be damaged.

  Therefore, by executing the fuel injection amount restriction control as in this embodiment, the exhaust pressure in the exhaust upstream portion 41a is reduced before the determination of the fixation of the movable vane 5c is completed, as shown in FIG. The exhaust pressure can be lower than the first predetermined exhaust pressure. Thereby, a turbocharger such as a small turbocharger that has a high turbocharge response and is highly likely to cause the turbine 5b to be in an overspeed state while the movable vane 5c is fixed. However, it is possible to quickly reduce the exhaust pressure in the exhaust upstream portion 41a and suppress the turbine from being over-rotated, thereby preventing the turbocharger from being damaged.

  As described above, in the present embodiment, the PCM 50 detects the detected engine speed detected by the engine speed sensor 110 when the detected exhaust pressure detected by the exhaust pressure sensor 117 is equal to or higher than the first predetermined exhaust pressure. Based on the detected nozzle opening detected by the nozzle position sensor 123, an upper limit fuel injection amount is set, and fuel injection amount restriction control is performed to limit the fuel injection amount to the upper limit fuel injection amount or less. Therefore, when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure and the turbine 5b is likely to be in an overspeed state, it is determined whether or not the movable vane 5c is in a fixed state. Without waiting for the exhaust gas, the exhaust pressure in the exhaust upstream portion 41a can be quickly reduced, and the exhaust energy for rotating the turbine 5b can be reduced. As a result, the turbocharger 5 can be prevented from being damaged by appropriately controlling the rotational speed of the turbine 5b.

  The present invention is not limited to the embodiment described above, and can be substituted without departing from the spirit of the claims.

  For example, in the above-described embodiment, the turbocharger 5 has a configuration in which a plurality of movable vanes 5c are arranged around the turbine 5b. A configuration may be adopted in which only one movable damper for adjusting the cross-sectional area of the exhaust gas is disposed at the inlet to 153a.

  In the above-described embodiment, the turbocharger 5 is a relatively small turbocharger. However, the turbocharger 5 is not limited to this, and the turbocharger 5 has a large supercharge response that is lower than that of the small turbocharger. A turbocharger may be used.

  The above-described embodiments are merely examples, and the scope of the present invention should not be interpreted in a limited manner. The scope of the present invention is defined by the scope of the claims, and all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

  INDUSTRIAL APPLICABILITY The present invention is useful as a control device and a control method for a supercharged engine having a turbocharger having a movable member for adjusting a flow passage cross-sectional area of exhaust gas in an inlet passage to a turbine.

1 Intake passage 5 Turbocharger 5a Compressor 5b Turbine 5c Movable vane (movable member)
20 Fuel injection valve 25 Crankshaft (engine output shaft)
41 Exhaust passage 41a Exhaust upstream portion (portion on the exhaust upstream side of the turbine in the exhaust passage)
50 Powertrain control module (channel cross-sectional area estimation means, fuel supply amount control means, upper limit fuel supply amount setting means)
107 Supercharging pressure sensor (supercharging pressure detection means)
110 engine speed sensor (engine speed detection means)
117 Exhaust pressure sensor (exhaust pressure detecting means)
123 Nozzle position sensor E Engine

Claims (8)

A control device for a supercharged engine,
A fuel injection valve configured to be able to supply fuel into the combustion chamber of the engine;
A turbine provided in the exhaust passage of the engine and a compressor provided in the intake passage of the engine, and a turbo engine that drives the compressor by rotating the turbine by exhaust gas flowing in the exhaust passage. A turbocharger comprising one or a plurality of movable members configured to change a cross-sectional area of the exhaust gas in the exhaust gas inlet passage to the turbine in the exhaust passage. Machine,
Exhaust pressure detecting means for detecting the pressure of the exhaust gas in the exhaust upstream side of the turbine in the exhaust passage;
A flow passage cross-sectional area detecting or estimating means for detecting or estimating a flow passage cross-sectional area of the exhaust gas in the inlet passage;
Engine speed detecting means for detecting the engine speed from the rotation angle of the output shaft of the engine;
Fuel supply amount control means for controlling the amount of fuel supplied from the fuel injection valve to the combustion chamber;
When the detected exhaust pressure detected by the exhaust pressure detecting means is equal to or higher than a first predetermined exhaust pressure, the flow path cross-sectional area detected or estimated by the flow path cross-sectional area detecting or estimating means, and the engine speed An upper limit fuel supply amount setting means for setting an upper limit fuel supply amount based on the engine speed detected by the detection means,
The fuel supply amount control means sets the fuel supply amount per cycle of the engine to an upper limit set by the upper limit fuel supply amount setting means when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure. A control apparatus for an engine with a supercharger, which is configured to execute a fuel supply amount restriction control that restricts the fuel supply amount to be equal to or less than a fuel supply amount. The control device for an engine with a supercharger according to claim 1,
The fuel supply amount control means is configured to supply the fuel in the fuel supply amount restriction control when the detected exhaust pressure is equal to or greater than a second predetermined exhaust pressure set to a value larger than the first predetermined exhaust pressure. A control device for a supercharged engine, characterized in that the amount is set to zero. In the supercharger-equipped engine control device according to claim 1 or 2,
A supercharging pressure detecting means for detecting the supercharging pressure of the intake air by the compressor;
The upper limit fuel supply amount setting means is configured such that when the detected boost pressure detected by the boost pressure detecting means is equal to or higher than a predetermined boost pressure, the detected exhaust pressure is less than the predetermined exhaust pressure. The upper limit fuel supply amount is set based on the flow path cross-sectional area detected or estimated by the flow path cross-sectional area detection or estimation means and the engine speed detected by the engine speed detection means. ,
The fuel supply amount control means is when the detected exhaust pressure is less than the first predetermined exhaust pressure when the detected supercharging pressure detected by the supercharging pressure detecting means is greater than or equal to the predetermined supercharging pressure. However, the control device for the supercharged engine is configured to execute the fuel supply amount restriction control. The supercharger-equipped engine control device according to claim 2,
The fuel supply amount control means determines whether the fuel supply amount is the detected exhaust pressure in the fuel supply amount restriction control when the detected exhaust pressure is not less than the first predetermined exhaust pressure and less than the second predetermined exhaust pressure. When set based on pressure, the fuel supply amount is set smaller as the detected exhaust pressure is higher than the first predetermined exhaust pressure. Engine control device. A fuel injection valve configured to be able to supply fuel into the combustion chamber of the engine;
A turbine provided in the exhaust passage of the engine and a compressor provided in the intake passage of the engine, and a turbo engine that drives the compressor by rotating the turbine by exhaust gas flowing in the exhaust passage. A turbocharger comprising one or a plurality of movable members configured to change a cross-sectional area of the exhaust gas in the exhaust gas inlet passage to the turbine in the exhaust passage. A method of controlling a turbocharged engine comprising a machine,
An exhaust pressure detecting step for detecting the pressure of the exhaust gas in the exhaust gas upstream side of the turbine in the exhaust passage;
A flow passage cross-sectional area detection or estimation step for detecting or estimating the flow passage cross-sectional area of the exhaust gas in the inlet passage;
An engine speed detection step of detecting the engine speed from the rotation angle of the output shaft of the engine;
A fuel supply amount setting step for setting a supply amount of fuel supplied from the fuel injection valve to the combustion chamber;
When the detected exhaust pressure detected in the exhaust pressure detection step is equal to or higher than a first predetermined exhaust pressure, the flow passage cross-sectional area detected or estimated in the flow passage cross-sectional area detection or estimation step, and the engine An upper limit fuel supply amount setting step for setting an upper limit fuel supply amount based on the engine speed detected in the rotation speed detection step,
In the fuel supply amount setting step, when the detected exhaust pressure is equal to or higher than the first predetermined exhaust pressure, the fuel supply amount per cycle of the engine is set to the upper limit fuel set in the upper limit fuel supply amount setting step. A method for controlling an engine with a supercharger, characterized in that it is a step of setting to a supply amount or less. In the control method of the supercharged engine according to claim 5,
The fuel supply amount setting step is a step of setting the fuel supply amount to 0 when the detected exhaust pressure is equal to or greater than a second predetermined exhaust pressure set to a value larger than the first predetermined exhaust pressure. A control method for an engine with a supercharger. In the control method of the engine with a supercharger according to claim 5 or 6,
A supercharging pressure detecting step of detecting the supercharging pressure of the intake air by the compressor;
In the upper limit fuel supply amount setting step, when the detected boost pressure detected in the boost pressure detecting step is equal to or higher than a predetermined boost pressure, the detected exhaust pressure is less than the predetermined exhaust pressure. The upper limit fuel supply amount based on the detected or estimated flow passage cross-sectional area and the detected engine speed,
The fuel supply amount setting step is when the detected exhaust pressure is less than the first predetermined exhaust pressure when the detected supercharging pressure detected in the supercharging pressure detecting step is greater than or equal to a predetermined supercharging pressure. And a method for controlling a supercharged engine, wherein the fuel supply amount per cycle of the engine is set to be equal to or less than the upper limit fuel supply amount. In the control method of the engine with a supercharger according to claim 6,
The fuel supply amount setting step is performed when the fuel supply amount is set based on the detected exhaust pressure when the detected exhaust pressure is greater than or equal to the first predetermined exhaust pressure and less than the second predetermined exhaust pressure. The supercharged engine control method is a step of setting the fuel supply amount to be smaller as the detected exhaust pressure is higher than the first predetermined exhaust pressure.

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