EP3055519B1 - Internal combustion engine - Google Patents
Internal combustion engine Download PDFInfo
- Publication number
- EP3055519B1 EP3055519B1 EP14787299.8A EP14787299A EP3055519B1 EP 3055519 B1 EP3055519 B1 EP 3055519B1 EP 14787299 A EP14787299 A EP 14787299A EP 3055519 B1 EP3055519 B1 EP 3055519B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- cam
- linking
- hydraulic pressure
- valve
- usage
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Not-in-force
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
- F01L1/00—Valve-gear or valve arrangements, e.g. lift-valve gear
- F01L1/26—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of two or more valves operated simultaneously by same transmitting-gear; peculiar to machines or engines with more than two lift-valves per cylinder
- F01L1/267—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of two or more valves operated simultaneously by same transmitting-gear; peculiar to machines or engines with more than two lift-valves per cylinder with means for varying the timing or the lift of the valves
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
- F01L13/00—Modifications of valve-gear to facilitate reversing, braking, starting, changing compression ratio, or other specific operations
- F01L13/0015—Modifications of valve-gear to facilitate reversing, braking, starting, changing compression ratio, or other specific operations for optimising engine performances by modifying valve lift according to various working parameters, e.g. rotational speed, load, torque
- F01L13/0036—Modifications of valve-gear to facilitate reversing, braking, starting, changing compression ratio, or other specific operations for optimising engine performances by modifying valve lift according to various working parameters, e.g. rotational speed, load, torque the valves being driven by two or more cams with different shape, size or timing or a single cam profiled in axial and radial direction
Definitions
- the present invention relates to an internal combustion engine such as known from EP0297791 A1 .
- Patent Document 1 discloses a variable operated-valve structure of an internal combustion engine having an operation determination means that detects an operation hydraulic pressure and determines operation condition of a variable valve lift structure based on a detected hydraulic pressure. Patent Document 1 discloses that a usage time of a low-speed cam and a usage time of a high-speed cam by comparing the operation hydraulic pressure with a predetermined value.
- the present invention has an object to provide an internal combustion engine that is callable of preferably determining a switching phase of a usage cam by a variable operated-valve structure.
- An internal combustion engine includes: a plurality of cams that are used for driving a valve; a cam-switching type variable operated-valve structure that has a locker arm portion and a plurality of hydraulic linking structures, the locker arm portion having a plurality of oscillation portions that individually oscillate according to cam profiles of the cams and mediate power conducted from a camshaft having the cams to the valve, the plurality of linking structures performing linking and canceling the linking between two of the plurality of oscillation portions with a lock member, the variable operated-valve structure selecting a usage cam that is used for driving the valve from the cams; and a determination unit that determines at least one of a condition of the lock member and a switching phase of the usage cam according to the condition of the lock member based on changing of a hydraulic pressure according to the switching of the usage cam.
- the determination unit may determine termination of an operation of the lock member in a linking structure of the plurality of linking structures that performs linking or canceling the linking during the switching of the usage cam based on a value and changing width of a hydraulic pressure detected and stored when the valve does not perform lifting, the hydraulic pressure changing according to a movement of the lock member in the linking structure of the plurality of linking structures that performs linking or cancelling the linking.
- variable operated-valve structure may have an oil path that penetrates the plurality of oscillation portions under a condition that the valve does not perform lifting; and the determination unit may determine the usage cam based on a reduction condition of a hydraulic pressure conducted by the oil path including with or without reduction of the hydraulic pressure.
- the variable operated-valve structure may be provided at least one of on an inlet side and on an exhaust side and has a plurality of the locker arm portions that are respectively provided in each of a plurality of cylinders; the locker arm portions may share the oil path among the plurality of cylinders at least one of on the inlet side and on the exhaust side, or the locker arm portions share the oil path among the plurality of cylinders both on the inlet side and on the exhaust side; and the variable operated-valve structure may share the oil path between the inlet side and the exhaust side.
- the oil path also may act as a lubricant oil path to supply oil for lubrication.
- the oil path may be different from an oil path to supply a hydraulic pressure to the plurality of linking structures.
- FIG. 1 illustrates an overall structure diagram of an internal combustion engine 50A and around the internal combustion engine 50A.
- FIG. 2 illustrates a schematic structure diagram of the internal combustion engine 50A.
- FIG. 3 illustrates a schematic structure of a variable operated-valve structure 60A.
- FIG. 3 illustrates the variable operated-valve structure 60A together with a camshaft 65.
- the internal combustion engine 50A is an internal combustion engine of a compression ignition type, and has a plurality of (four in this case) cylinders 51a.
- the internal combustion engine 50A is mounted on a vehicle not illustrated together with an inlet system 10, an exhaust system 20 and an exhaust reflux system 40.
- the internal combustion engine 50A may be an internal combustion engine of a spark ignition type.
- the inlet system 10 has an air flow meter 11, an intercooler 12 and an intake manifold 13.
- the air flow meter 11 measures an intake air amount.
- the intercooler 12 cools the intake air.
- the intake manifold 13 distributes the intake air into each cylinder 51a of the internal combustion engine 50A.
- the exhaust system 20 has an exhaust manifold 21 and a catalyst 22.
- the exhaust manifold 21 converges exhausted air from each cylinder 51a.
- the catalyst 22 cleans up the exhausted air.
- a supercharger 30 is provided in the inlet system 10 and the exhaust system 20. The supercharger 30 supercharges intake air to the internal combustion engine 50A.
- the exhaust reflux system 40 has an EGR pipe 41, an EGR cooler 42 and an EGR valve 43.
- the EGR pipe 41 communicates the inlet system 10 with the exhaust system 20.
- the EGR pipe 41 communicates a pathway-assembly portion of the intake manifold 13 with another pathway-assembly portion of the exhaust manifold 21.
- the EGR cooler 42 cools the refluxed exhaust air.
- the EGR valve 43 adjusts an amount of the refluxed exhaust air.
- the internal combustion engine 50A has a cylinder block 51, a cylinder head 52, a piston 53, an inlet valve 54, an exhaust valve 55, a fuel injection valve 56, a variable operated-valve structure 60A and a camshaft 65, in addition to the ECU 70A.
- the piston 53, the inlet valve 54, the exhaust valve 55, and the fuel injection valve 56 are provided in each cylinder 51a.
- the cylinder block 51 has the cylinder 51a.
- the cylinder 51a houses the piston 53.
- the cylinder head 52 is fixed to an upper face of the cylinder block 51.
- a combustion chamber E is a space surrounded by the cylinder block 51, the cylinder head 52 and the piston 53.
- the piston 53 is adjacent to the combustion chamber E.
- the cylinder head 52 has an inlet port 52a guiding inlet air to the combustion chamber E and an exhaust port 52b exhausting gas from the combustion chamber E. And, the cylinder head 52 has an inlet valve 54 opening or closing the inlet port 52a and an exhaust valve 55 opening or closing the exhaust port 52b.
- a plurality of (two) inlet valves 54 and a plurality of (two) exhaust valves 55 are provided in each cylinder 51a.
- the fuel injection valve 56 is provided in the cylinder head 52 and injects fuel to the combustion chamber E.
- the variable operated-valve structure 60A is provided in the cylinder head 52.
- the variable operated-valve structure 60A is a cam-switch type variable operated-valve structure, and selects a usage cam used for driving the inlet valve 54 from a first cam Ca, a second cam Cb and a third cam Cc.
- the cams Ca, Cb and Cc are provided on the camshaft 65 and form a plurality of cam used for driving the inlet valve 54.
- the number of the plurality of the cams may be three or more.
- the cams Ca, Cb and Cc are respectively provided in each cylinder 51a. Therefore, the cams Ca, Cb and Cc are used for driving the inlet valve 54 in each cylinder 51a.
- the variable operated-valve structure 60A selects a usage cam used for driving the inlet valve 54 from the cams Ca, Cb and Cc in each cylinder 51a.
- the variable operated-valve structure 60A has a cam-contact portion 61, a valve drive portion 62, a locker arm portion 63 and a locker arm shaft 64.
- the cam-contact portion 61, the valve drive portion 62 and the locker arm portion 63 are provided in each cylinder 51a and form a unit U.
- the cam-contact portion 61 is a cam follower.
- a plurality of (three) cam-contact portions 61 are respectively provided in the cams Ca, Cb and Cc.
- a cam-contact portion 61a is a cam-contact-portion contacting the cam Ca in the cam-contact portion 61.
- a cam-contact portion 61b is a cam-contact portion contacting the cam Cb.
- a cam-contact portion 61c is a cam-contact portion contacting the cam Cc.
- a plurality of the cam-contact portions 61 are respectively provided in the locker arm portion 63.
- the valve drive portion 62 is provided in the locker arm portion 63.
- the number of the valve drive portion 62 (two) is the same as that of the inlet valve 54 provided in each cylinder 51a.
- the valve drive portion 62 conducts driving force to the inlet valve 54.
- a screw tappet may be applied to the valve drive portion 62.
- the valve drive portion 62 may be a part of the locker arm portion 63.
- the locker arm portion 63 is driving-force mediation portion and mediates driving force conducted from the camshaft 65 to the inlet valve 54 together with the cam-contact portion 61 and the valve drive portion 62.
- the locker arm shaft 64 is inserted into the locker arm portion 63.
- the locker arm shaft 64 supports the locker arm portion 63 so that the locker arm portion 63 can slide.
- the locker arm shaft 64 is a common shaft in the units U provided in each cylinder 51a.
- the locker arm shaft 64 extends along an extending direction of the camshaft 65.
- the locker arm portion 63 has an oscillation portions 63a, 63b and 63c acting as a plurality of oscillation portions.
- the oscillation portions 63a, 63b and 63c are arranged along the extending direction of the camshaft 65 in this order.
- the oscillation portions 63a, 63b and 63c individually oscillates according to a cam profile of the cams Ca, Cb and Cc, and mediate driving force conducted from the camshaft 65 to the inlet valve 54.
- the oscillation portion 63a acting as a first oscillation portion has a cam-contact portion 61a. Therefore, the oscillation portion 63a oscillates according to the cam Ca.
- the oscillation portion 63b acting as a second oscillation portion has the cam-contact portion 61b.
- the oscillation portion 63c acting as a third oscillation portion has the cam-contact portion 61c. Therefore, the oscillation portion 63b oscillates according to the cam Cb.
- the oscillation portion 63c oscillates according to the cam Cc.
- the valve drive portion 62 is provided in the oscillation portion 63b and the oscillation portion 63c. Therefore, in the locker arm portion 63, the oscillation portions 63b and 63c of the oscillation portions 63a, 63b and 63c drive the inlet valve 54.
- the oscillation portions 63a, 63b and 63c are supported by the locker arm shaft 64 so that the oscillation portions 63a, 63b and 63c can individually slide.
- the locker arm portion 63 has a linking structures 631 and 632 acting as a plurality of linking structures.
- the linking structures 631 and 632 are hydraulic type and links between two of the oscillation portions 63a, 63b and 63c and cancels the linking.
- the linking structure 631 acting as a first linking structure links between the oscillation portions 63b and 63c and cancels the linking.
- the linking structure 632 acting as a second linking structure links between the oscillation portions 63a and 63c and cancels the linking.
- the linking structure 632 performs linking and canceling the linking between the oscillation portions 63a and 63b.
- the oscillation portion 63a has a biasing member such as a return spring that biases the cam-contact portion 61a toward the cam Ca so that the cam Ca is capable of driving the inlet valve 54. Therefore, the oscillation portion 63a makes the cam-contact portion 61a contact the cam Ca under a condition that the linking is canceled.
- a biasing member such as a return spring that biases the cam-contact portion 61a toward the cam Ca so that the cam Ca is capable of driving the inlet valve 54. Therefore, the oscillation portion 63a makes the cam-contact portion 61a contact the cam Ca under a condition that the linking is canceled.
- FIG. 4 illustrates the linking structures 631 and 632.
- the linking structure 631 has a support portions H11 and H12 and pins Pn11 and Pn12, and a spring Sp1.
- the oscillation portion 63b has the support portion H11.
- the oscillation portion 63c has the support portion H12.
- the support portions H11 and H12 are arranged along an extending direction of the camshaft 65 when the inlet valve 54 does not perform lifting.
- the support portions H11 and H12 have a cylinder shape having a bottom and have an identical inner diameter.
- the "identical" includes a case where the diameters are different from each other within a production error. The same shall apply hereafter.
- the pin Pn11 is at least supported by the support portion H11 of the support portions H11 and H12.
- the pin Pn12 is at least supported by the support portion H12 of the support portions H11 and H12.
- the pins Pn11 and Pn12 have a cylinder shape and have an identical outer diameter.
- the outer diameter of the pins Pn11 and Pn 12 is smaller than the inner diameter of the support portions H11 and H12 by a clearance for sliding.
- a spring chamber G11 is formed between a bottom of the support portion H11 and the pin Pn11.
- the spring chamber G11 is a hydraulic chamber.
- a hydraulic chamber G12 is formed between a bottom of the support portion H12 and the pin Pn 12.
- the spring Sp1 is provided in the spring chamber G11. The spring Sp1 biases the pin Pn11.
- An OCV (Oil Control Valve) 81 is connected to the linking structure 631.
- the OCV 81 is connected to the spring chamber G11 via an oil path R11, and is connected to the hydraulic chamber G12 via an oil path R12.
- the OCV 81 releases the hydraulic pressure from the hydraulic chamber G12 and conducts a hydraulic pressure P in to the spring chamber G11, when the OCV 81 is off.
- the OCV 81 conducts the hydraulic pressure P in to the hydraulic chamber G12 and releases the hydraulic pressure from the spring chamber G11, when the OCV 81 is on.
- the hydraulic pressure P in is common supplied hydraulic pressure to the linking structures 631 and 632, and is conducted to the linking structures 631 and 632 via the OCVs 81 and 82.
- the hydraulic pressure P in may be a main gallery hydraulic pressure.
- the linking structure 631 links between the oscillation portions 63b and 63c when the OCV 81 is off.
- the hydraulic pressure P in conducted to the spring chamber G11 via a spring Sp1 and the OCV 81 moves the pins Pn11 and Pn12 against the hydraulic pressure released from the hydraulic chamber G12 via the OCV 81.
- the oscillation portions H11 and H12 support the pin Pn11
- the oscillation portions 63b and 63c are linked with each other.
- the linking structure 631 can link between the oscillation portions 63b and 63c by moving the pins Pn11 and Pn12 with use of the spring Sp1 even if the hydraulic pressure P in does not occur.
- the linking structure 631 cancels the linking between the oscillation portions 63b and 63c.
- the hydraulic pressure P in conducted to the hydraulic chamber G12 via the OCV 81 moves the pins Pn11 and Pn12 against the hydraulic pressure released from the spring chamber G11 via the OCV 81.
- the pin Pn11 is supported by the support portion H11, the linking between the oscillation portions 63b and 63c is canceled.
- the linking structure 632 has a support portions H21, H22 and H23, pins Pn21, Pn22 and Pn23, and a spring Sp2.
- the oscillation portion 63b has the support portion H21.
- the oscillation portion 63a has the support portion H22.
- the oscillation portion 63c has the support portion H23.
- the support portions H21, H22 and H23 are arranged along an extending direction of the camshaft 65 when the inlet valve 54 does not perform the lifting.
- the support portions H21 and H23 have a cylinder shape having a bottom.
- the support portion H22 has a cylinder shape.
- the support portions H21, H22 and H23 have an identical inner diameter.
- the pin Pn21 is at least supported by the support portion H21 of the support portions H21 and H22.
- the pin Pn22 is at least supported by the support portion H22 of the support portions H22 and H23.
- the pin Pn23 is supported by the support portion H23.
- the pins Pn21, Pn22 and Pn23 have a cylinder shape and have an identical outer diameter. The outer diameter of the pins Pn21, Pn22 and Pn23 is smaller than the inner diameter of the support portions H21, H22 and H23 by a clearance for sliding.
- a hydraulic chamber G21 is formed between a bottom of the support portion H21 and the pin Pn21.
- a spring chamber G22 is formed between a bottom of the support portion H23 and the pin Pn23.
- the spring Sp2 is provided in the spring chamber G22.
- the spring Sp2 biases the pin Pn23.
- the OCV 82 is connected to the linking structure 632.
- the OCV 82 is connected to the hydraulic chamber G21 via an oil path R2.
- the OCV 82 conducts the hydraulic pressure P in to the hydraulic chamber G21 when the OCV 82 is on.
- the OCV 82 releases the hydraulic pressure P in from the hydraulic chamber G21 when the OCV 82 is off.
- the linking structure 632 links between the oscillation portions 63a and 63c when the OCV 82 is on.
- the hydraulic pressure P in conducted to the hydraulic chamber G21 via the OCV 82 moves the pins Pn21, Pn22 and Pn23 against the biasing force of the spring Sp2.
- the oscillation portions 63a and 63c are linked with each other.
- the linking structure 632 links between the oscillation portions 63a and 63b.
- the oscillation portions 63a and 63b are linked.
- the linking structure 632 cancels the linking between the oscillation portions 63a and 63c.
- the spring Sp2 moves the pins Pn21, Pn22 and Pn23 against the hydraulic pressure released from the hydraulic chamber G21 via the OCV 82.
- the linking structure 632 cancels the linking between the oscillation portions 63a and 63b.
- the pin Pn21 is supported by the support portion H21, the linking between the oscillation portions 63a and 63b is canceled.
- the pin Pn11 links between the oscillation portions 63b and 63c and cancels the linking.
- the pin Pn22 links between the oscillation portions 63a and 63c and cancels the linking.
- the pins Pn11 and Pn22 act as a lock member.
- the pin Pn 11 acts a first lock member.
- the pin Pn22 acts as a second lock member.
- the pin Pn21 linking between the oscillation portions 63a and 63b and canceling the linking instead of the pin Pn22 may act as a lock member.
- at least one of the pins Pn21 and Pn22 may act as the lock member.
- the oil paths R11, R12 and R2 may be provided according to a linking structure of the linking structures 631 and 632 via the locker arm shaft 64.
- FIG. 5A to FIG. 5C illustrate phases of cam switching phase.
- FIG. 5A illustrates a phase where the cam Cb is the usage cam.
- FIG. 5B illustrates a phase where the cam Cb is the usage cam.
- FIG. 5C illustrates a phase where the cam Cc is the usage cam.
- the camshaft 65 and the lift curved-lines La, Lb and Lc are illustrated together with the unit U.
- the lift curved-line La is a curved line obtained in a case where the inlet valve 54 is driven in accordance with the cam profile of the cam Ca.
- the lift curved-line Lb is a curved line obtained in a case where the inlet valve 54 is driven in accordance with the cam profile of the cam Cb.
- the lift curved-line Lc is a curved line obtained in a case where the inlet valve 54 is driven in accordance with the cam profile of the cam Cc.
- variable operated-valve structure 60A may use the cam Cb as the usage cam when the linking structure 631 links between the oscillation portions 63b and 63c and the linking structure 632 cancels the linking between the oscillation portions 63a and 63c and the linking between the oscillation portions 63a and 63b.
- the cams Cb and Cc may be used as the usage cam when the linking structure 631 cancels the linking between the oscillation portions 63b and 63c and the linking structure 632 cancels the linking between the oscillation portions 63a and 63c and the liking between the oscillation portions 63a and 63b.
- FIG. 5A the variable operated-valve structure 60A may use the cam Cb as the usage cam when the linking structure 631 links between the oscillation portions 63b and 63c and the linking structure 632 cancels the linking between the oscillation portions 63a and 63c and the liking between the oscillation portions 63a and 63b.
- the cam Ca may be used as the usage cam when the linking structure 631 links between the oscillation portions 63b and 63c and the linking structure 632 links between the oscillation portions 63a and 63c and between the oscillation portions 63a and 63b.
- the cams Ca, Cb and Cc are arranged along an extending direction of the camshaft 65 in this order.
- the cams Ca, Cb and Cc have a different cam profile.
- the cam profiles of the cams Ca, Cb and Cc are set so that a lift amount of the inlet valve 54 caused by the cam Ca is more than that by the cam Cb, and the amount caused by the cam Cb is more than that by the cam Cc.
- the cam profiles of the cams Ca, Cb and Cc are set so that the lift curved-line Lb is included in the lift curved-line La, and the lift curved-line Lc is included in the Lift curved-line Lb.
- the variable operated-valve structure 60A has a plurality of modes as a cam switching mode.
- the cam switching mode is distinguished with respect to each switching phase of a usage cam.
- the switching phase of the usage cam can be specified by a switching from one of two usage patterns of a plurality of usage patterns to the other.
- the usage pattern of the usage cam includes a first pattern using the cam Cb as the usage cam, a second pattern using the cams Cb and Cc as the usage cam, and a third pattern using the cam Ca as the usage cam.
- the cam switching mode includes the following first to third modes.
- the first mode is a mode in which the switching phase of the usage cam is a switching from the cam Cb to the cams Cb and Cc.
- the second mode is a mode in which the switching phase of the usage cam is a switching from the cam Cb to the cam Ca.
- the third mode is a mode in which the switching phase of the usage cam is a switching from the cams Cb and Cc to the cam Ca.
- a plurality of modes that the variable operated-valve structure 60A has as a cam switching mode are the first to third modes and fourth to sixth modes of which mode is opposite to the first to third modes.
- the ECU 70A illustrated in FIG. 1 and so on is an electronic control device.
- the EGR valve 43, the fuel injection valve 56, the OCVs 81 and 82 and so on are electrically connected to the ECU 70A as a controlled object.
- the air flow meter 11, a crank angle sensor 91 to detect a crank angle q, an accelerator position sensor 92 to request acceleration to the internal combustion engine 50A, and a hydraulic sensors 93 and 94 to detect the hydraulic pressures P1 and P2 are electrically connected to the ECU 70A as a sensor-switch portion.
- the hydraulic pressure P1 is a hydraulic pressure in the spring chamber G11.
- the hydraulic pressure P2 is a hydraulic pressure in the hydraulic chamber G21.
- the hydraulic pressure P1 can be detected via an oil path for detecting hydraulic pressure from the spring chamber G11.
- the hydraulic pressure P2 can be detected via the oil path from the hydraulic chamber G21.
- the ECU 70A detects a rotation number Ne that is an engine rotation number based on an output of the crank angle sensor 91.
- a determination unit and a decision unit are realized in the ECU 70A.
- the units may be realized in a plurality of electronic control devices.
- the determination unit determines a condition of a pin acting as a lock member (in concrete, at least one of the pins Pn11 and Pn22) based on the changing of the hydraulic pressure caused by the switching of the usage cam.
- the determination unit determines the condition of the pin acting as the lock member based on the hydraulic pressure (hereinafter referred to as object hydraulic pressure) changing according to a movement of the pin acting as the lock member when the inlet valve 54 does not perform the lifting in the linking structure performing linking or canceling the linking of the linking structures 631 and 632 during switching the usage cam.
- the object hydraulic pressure is hydraulic pressure used for determining.
- the object hydraulic pressure is at least one of the hydraulic pressures P1 and P2.
- the decision unit decides at least one of the hydraulic pressures P1 and P2 as the object hydraulic pressure based on the cam switching mode.
- the object hydraulic pressure may be specified from the hydraulic pressures P1 and P2 in advance in accordance with the cam switching mode.
- the object hydraulic pressure is a hydraulic pressure detected with a time element. In concrete, the object hydraulic pressure may be hydraulic pressure obtained according to the crank angle q or the like.
- the determination unit determines the condition of the pin Pn11 based on the hydraulic pressure P1 when the object hydraulic pressure is the hydraulic pressure P1.
- the determination unit determines the condition of the pin Pn22 based on the hydraulic pressure P2 when the object hydraulic pressure is the hydraulic pressure P2.
- the determinations unit determines the conditions of the pins Pn11 and Pn21 when the object hydraulic pressure is the hydraulic pressures P1 and P2.
- the determination unit performs a first determination whether an object pin is operated (operation starts).
- the object pin is a pin acting as the lock member in the linking structure performing linking or canceling the linking during switching the usage cam of the linking structures 631 and 632, and is at least one of the pins Pn11 and Pn22, in concrete.
- the determination unit performs a second determination whether the switching of the usage cam is terminated. When the determinations performs the second determination, the determination unit determines whether the operation of the objective pin is terminated based on the value and the changing width of the object hydraulic pressure that are detected and stored when the inlet valve 54 does not perform the lifting.
- FIG. 6 illustrates the determination.
- FIG. 6 illustrates an example of the changing of the object hydraulic pressure during the switching of the usage cam together with the lift amount of the inlet valve 54 and on and off of the OCV 81.
- the object hydraulic pressure and the on and off of the OCV 81 are illustrated with a solid line, and the lift amount of the inlet valve 54 is illustrated with a broken line.
- FIG. 6 illustrates a case where the cam switching mode is the fourth mode (switching from the cams Cb and Cc to the cam Cb), and the object hydraulic pressure is the hydraulic pressure P1.
- a hydraulic pressure P1' of the hydraulic chamber G12 is also illustrated.
- a predetermined value a1 is a value to detect a start of the changing of the object hydraulic pressure according to the switching of the usage cam.
- the determination unit determines that the object pin operates when a difference between an initial value ini and a minimum value min of the object hydraulic pressure detected and stored when the inlet valve 54 does not perform the lifting is more than a predetermined value a3.
- the period in which the inlet valve 54 does not perform the lifting is a base circle section.
- the base circle section is a section in which a base circle portion of the usage cam decides the lift amount of the inlet valve 54.
- the predetermined value a3 is a value for detecting pressure changing (in concrete, decrease of pressure) occurred by starting of the movement of the objective pin.
- the determination unit performing the first determination determines whether the object pin operates based on the changing at the starting of the operation of the object pin that is a changing of the hydraulic pressure caused by the switching of the usage cam.
- the determination unit determines whether the object pin locks by determining whether the object pin operates until a given time passes. The given time is a normal allowed time to terminate the switching of the usage cam.
- the determination unit determines whether the operation of the object pin is terminated based on a minimum value min and a changing width max-min of the objective hydraulic pressure detected and stored when the inlet valve 54 does not perform the lifting.
- the minimum value min is larger than a predetermined value a2 and the changing width max-min is less than a predetermined value b, the determination unit determines that the operation of the object pin is terminated.
- the changing width max-min is a difference between the maximum value max and the minimum value min of the object hydraulic pressure.
- the predetermined value b is a value for determining whether the changing of the object hydraulic pressure converges.
- the predetermined value a2 is set so that the object hydraulic pressure does not pass after the operation of the object pin is terminated. In this manner, the determination unit performing the second determination determines the termination of the operation of the object pin based on the convergence of the hydraulic pressure changing according to the switching of the usage cam. In the second determination, the object hydraulic pressure can be stored with respect to each base circle section.
- Values of the predetermined values a1, a2, a3 and b may be different between a case where the object hydraulic pressure is the hydraulic pressure P1 and a case where the object hydraulic pressure is the hydraulic pressure P2.
- the values of the predetermined values a1, a2, a3 and b may be changed according to the hydraulic pressure P in .
- the object hydraulic pressure may be a hydraulic pressure P1' acting as a back pressure instead of the hydraulic pressure P1 acting as a supply pressure.
- the determination unit may determine that the object pin operates when a difference between an initial value ini and a maximum value max of the hydraulic pressure P1' detected and stored when the inlet valve 54 does not perform the lifting is larger than a predetermined value a3'.
- the determination unit may determine that the operation of the object pin is terminated when the maximum value max is less than a predetermined value a2' and a changing width max-min is less than a predetermined value b'.
- the predetermined values a1', a2', a3'and b' may be set as in the case of the predetermined values a1, a2, a3 and b.
- the maximum value max corresponds to the value of the object hydraulic pressure in a case where the hydraulic pressure P1' is the object hydraulic pressure. Therefore, the value of the object hydraulic pressure may be the minimum value min when the object hydraulic pressure is the supply pressure, and the value of the object hydraulic pressure may be the maximum value max when the object hydraulic pressure is the back pressure.
- the determination unit may determine the condition of the pin acting as the lock member when a switching of the usage cam is requested.
- FIG. 7 illustrates a case where the switching of the usage cam is started in the fourth mode.
- the flowchart may start when the switching of the usage cam is requested.
- the ECU 70A detects the hydraulic pressure P1 (Step S1) and determines whether the detected hydraulic pressure P1 is more than the predetermined value a1 (Step S2).
- Step S3 When it is determined as "No” in the Step S2, the ECU 70A activates a timer (Step S3) and determines whether a given time passes (Step S4). When it is determined as "No” in the Step S4, the Step 1 is executed again. When it is determined as "Yes” in the Step S4, the determination unit determines that the OVC 81 is abnormal (Step S5). After the Step S5, the Step S1 is executed again. After the Step S5, the flowchart may be terminated.
- the ECU 70A determines whether the current time is in the base circle section (Step S11).
- the ECU 70A stores the hydraulic pressure P1[i] (Step S12).
- the hydraulic pressure P1[i] indicates the hydraulic pressure P1 of i-th base circle section.
- the number "i” is a number updated when the base circle section is transferred to a new base circle section. An initial value of the number "i” is one.
- the Step S1 is executed again. In this case, the hydraulic pressure P1[i] is stored in the Step S12 until it is determined as "No" in the Step S11 in the routine after that.
- the ECU 70A determines whether a flag F is off (Step S21).
- the flag F is a flag for determining that the object pin operates.
- the ECU 70A determines whether the difference between the initial value ini and the minimum value min of the stored hydraulic pressure P1[i] is larger than the predetermined value a3 (Step S22).
- the ECU 70A determines that the pin operates and turns the flag on (Step S23).
- ECU 70A deletes the stored hydraulic pressure P1[i] (Step S29) and executes the Step S1 again.
- Step S24 the ECU 70A determines whether a given time passes. In the Step S24, the ECU 70A determines based on whether the number "i" is larger than a threshold. The threshold may be determined by the engine operation condition. When it is determined as "Yes” in the Step S24, the ECU 70A determines that the object pin locks (Step S25). After the Step S25, the Step S1 is executed again. After the Step S25, the flowchart is terminated. When it is determined as "No” in the Step S24, the Step S29 is executed.
- Step S21 the ECU 70A determines whether the changing width max-min of the stored hydraulic pressure P1[i] is less than the predetermined value b (Step S26). When it is determined as "Yes” in the Step S21, the ECU 70A determines whether the minimum value min of the hydraulic pressure P1[i] is larger than the predetermined value a2 (Step S27). When it is determined as "No” in the Step S26 or the Step S27, a Step S29 is executed.
- Step S28 the ECU 70A determines that the operation of the object pin is terminated. After the Step S28, the Step S1 is executed again. After the Step S28, the flowchart may be terminated.
- the internal combustion engine 50A can preferably determine the switching phase of the usage cam performed by the variable operated-valve structure 60A in view of determination accuracy, by determining the condition of the pin acting as the lock member based on the changing of the hydraulic pressure according to the switching of the usage cam.
- the internal combustion engine 50A can preferably determine the termination of the switching of the usage cam in a point of timing by determining the termination of the operation of the object pin based on the object hydraulic pressure and the changing width max-min that are detected and stored when the inlet valve 54 does not perform the lifting.
- the internal combustion engine 50A can determine the timing at the start of the operation of the object pin by determining whether the object pin operates based on the changing of the object pin at the starting of the operation that is the changing of the hydraulic pressure according to the switching of the usage cam. When it is determined whether the object pin operates until the predetermined time passes, it is possible to determine whether the object pin locks.
- the internal combustion engine 50A can determine whether the object pin operates by determining that the object pin operates in a case where the difference between the initial value ini and the minimum value min is larger than the predetermined value a3 when the object hydraulic pressure is the supply pressure and in a case where the difference between the initial value ini and the maximum value max is larger than the predetermined value a3' when the object hydraulic pressure is the back pressure, with respect to the object hydraulic pressure that is detected and stored when the inlet valve 54 does not perform the lifting.
- An internal combustion engine in accordance with a second embodiment is substantially the same as the internal combustion engine 50A illustrated in FIG. 2 except for the following points.
- the internal combustion engine in accordance with the second embodiment has another variable operated-valve structure hereinafter referred to as the variable operated-valve structure 60B) instead of the variable operated-valve structure 60A, and has another ECU (hereinafter referred to as ECU 70B) instead of the ECU 70A.
- the internal combustion engine in accordance with second the embodiment has another hydraulic sensor (hereinafter referred to as hydraulic sensor 95) instead of the hydraulic sensors 93 and 94 as illustrated in FIG. 2 .
- the internal combustion engine in accordance with the second embodiment is hereinafter referred to as an internal combustion engine 50B.
- variable operated-valve structure 60B is substantially the same as the variable operated-valve structure 60A except for a point that a unit U' described later is provided instead of the unit U.
- the ECU 70B is substantially the same as the ECU 70A except for points that another determination unit is realized instead of the above-mentioned determination unit, the decision unit is not realized, the hydraulic sensor 95 is electrically coupled as a sensor-switch portion instead of the hydraulic sensors 93 and 94.
- the structure of the internal combustion engine 50B may be added to the internal combustion engine 50A by changing the structure of the internal combustion engine 50A.
- FIG. 8 illustrates the unit U'.
- the unit U' is substantially the same as the unit U expect for a point that the linking structures 631 and 632 have the oil path R3 that is different from the oil paths R11, R12 and R2 for supplying the hydraulic pressure.
- the difference of the locker arm portion 63 with or without the oil path R3 is not distinguished by the numeral.
- the oil paths R11, R12 and R2 are not illustrated.
- the oil path R3 is provided so as to penetrate the oscillation portions 63a, 63b and 63c under a condition that the inlet valve 54 does not perform the lifting.
- the locker arm portion 63 shares the oil path R3 between the plurality of cylinders 51a on the inlet side.
- the oil path R3 also acts as a lubricant oil path to supply oil for lubrication.
- the lubricant oil path is an oil path to supply oil to a lash adjuster.
- the valve drive portion 62 acts as the lash adjuster.
- the oil path R3 has the hydraulic sensor 95.
- the hydraulic sensor 95 is provided on the downstream side compared to the oscillation portions 63a, 63b and 63c in the oil path R3. Therefore, the hydraulic sensor 95 detects the hydraulic pressure P3 conducted by the oil path R3.
- the hydraulic pressure P3 is a hydraulic pressure conducted by the oil path R3 from the oscillation portions 63a, 63b and 63c.
- the ECU 70B realizes the determination unit to determine the switching phase of the usage cam based on the hydraulic pressure P3.
- FIG. 9A to FIG. 9D illustrate a determination method based on the hydraulic pressure P3.
- FIG. 9A illustrates a changing of the hydraulic pressure P3 when the cam Ca is the usage cam.
- FIG. 9B illustrates the changing of the hydraulic pressure P3 when the cam Cb is the usage cam.
- FIG. 9C illustrates a changing of the hydraulic pressure P3 when the cams Cb and Cc are the usage cam.
- FIG. 9D illustrates lift curved lines La, Lb and Lc. In FIG. 9A to FIG. 9D , the crank angle of the horizontal axis is common.
- the linking structure 631 links between the oscillation portions 63b and 63c with the pin Pn11, and the linking structure 632 links between the oscillation portions 63a and 63c with the pin Pn22. Therefore, in this case, the oscillation portions 63a, 63b and 63c integrally oscillate in accordance with the cam Ca. As a result, the hydraulic pressure P3 does not change as illustrated in FIG. 9A .
- the linking structure 631 links between the oscillation portions 63b and 63c with the pin Pn11 and cancels the linking between the oscillation portions 63a and 63c with the pin Pn22. Therefore, in this case, the oscillation portions 63b and 63c integrally oscillate in accordance with the cam Cb.
- the oscillation portion 63a oscillates in accordance with the cam Ca. In this case, when there is a difference between the oscillation direction of the oscillation portion 63a and the oscillation direction of the oscillation portions 63b and 63c, the oil path R3 is closed. As a result, as illustrated in FIG. 9B , when there is a difference between the oscillation direction of the oscillation portion 63a and the oscillation portions 63b and 63c, the hydraulic pressure P3 is reduced.
- the linking structure 631 cancels the linking between the oscillation portions 63b and 63c with the pin Pn11 and cancels the linking between the oscillation portions 63a and 63c with the pin Pn22. Therefore, in this case, the oscillation portion 63a oscillates in accordance with the cam Ca, the oscillation portion 63b oscillates in accordance with the cam Cb, and the oscillation portion 63c oscillates in accordance with the cam Cc. In this case, when there is a difference between the oscillation directions of the oscillation portions 63a and 63b, the oil path R3 is closed.
- the determination unit determines the switching phase of the usage cam according to the condition of the pin acting as the lock member based on the reduction condition of the hydraulic pressure P3 including with or without reduction.
- the reduction condition is a reduction period, for example.
- the reduction condition may be at least one of the reduction period, a reduction timing and a restoring timing of the hydraulic pressure P3.
- the determination unit determines which of the cams Ca, Cb and Cc the usage cam is.
- the determination unit determines the usage cam as the switching phase of the usage cam.
- the ECU 70B detects the hydraulic pressure P3 (Step S21), and determines whether the detected hydraulic pressure P3 is reduced (Step S22). When it is determined as "Yes” in the Step S22, the ECU 70B starts measuring the reduction period of the hydraulic pressure P3 (Step S23). Next, the ECU 70B determines whether the hydraulic pressure P3 is restored (Step S24). When it is determined as "No" in the Step S24, the Step S24 is executed again.
- Step S24 the ECU 70B terminates the measuring of the reduction period of the hydraulic pressure P3 (Step S25), and determines whether the reduction period of the hydraulic pressure P3 is a predetermined period (reduction period of the hydraulic pressure P3 when the cam Cb is the usage cam) (Step S28).
- Step S28 the ECU 70B determines that the cams Cb and Cc are the usage cam (Step S29). After the Step S28 and the Step S29, the Step S21 is executed again.
- Step S27 the ECU 70B determines whether there is reduction of the hydraulic pressure P3 during one combustion cycle.
- Step S21 the Step S21 is executed again.
- the ECU 70B determines that the cam Ca is the usage cam (Step S30). After the Step S30, the Step S21 is executed again.
- the internal combustion engine 50B determines the usage cam as the switching phase of the usage cam based on the reduction condition of the hydraulic pressure P3 including with or without the reduction.
- the internal combustion engine 50B can determine the switching phase of the usage cam by having the hydraulic sensor 95 in the oil path R3. Therefore, the internal combustion engine 50B can preferably determine the switching phase of the usage cam in viewpoints of the cost or mounting.
- the internal combustion engine 50B can determine the usage cam with a single hydraulic sensor 95 with respect to each cylinder 51a because the internal combustion engine 50B has a structure in which the locker arm portion 63 shares the oil path R3 between the plurality of cylinders 51a on the inlet side. That is, the internal combustion engine 50B can have the structure when preferably determining the switching phase of the usage cam in viewpoints of the cost and the mounting.
- the internal combustion engine 50B prevents or suppresses size-growing of the locker arm portion 63 for securing the oil path because the oil path R3 also acts as a lubricant oil path to supply oil for lubricant. It is preferable that the oil path R3 also acts as the lubricant oil path, in a point that no problem occurs because of the closing of the oil path R3 in accordance with the oscillation of the oscillation portions 63a to 63c even if the oil is supplied at an interval.
- the valve is the inlet valve 54.
- the valve may be an exhaust valve.
- the variable operated-valve structure may be provided on the inlet side and the exhaust side.
- the hydraulic sensor can be shared, when the locker arm portion shares an oil path corresponding to the oil path R3 between the plurality of cylinders on the inlet side and the exhaust side and the variable operated-valve structures share the oil path corresponding to the oil path R3 between the inlet side and the exhaust side.
- the structure has an advantage in cost.
- the variable operated-valve structure in a case where the valve is the exhaust valve is as follows.
- FIG. 11 is a first drawing of a main part of a variable operated-valve structure 60' that is another example.
- FIG. 12 is a second drawing of the main part of the variable operated-valve structure 60'.
- FIG. 13A and FIG. 13B illustrate a camshaft 65'.
- FIG. 13A illustrates an overall structure of the camshaft 65'.
- FIG. 13B illustrates a cross sectional view of cams Ca', Cb' and Cc' taken along a line A-A of FIG. 13A .
- FIG. 11 illustrates the camshaft 65' and the variable operated-valve structure 60'.
- FIG. 12 illustrates the OCVs 81' and 82' and the variable operated-valve structure 60'.
- the variable operated-valve structure 60' selects a usage cam for driving the exhaust valve 55 from the cams Ca', Cb' and Cc'.
- the camshaft 65' has the cams Ca', Cb' and Cc'.
- the cams Ca', Cb' and Cc' act as a plurality of (three) cams used for driving the exhaust valve 55.
- the cams Ca', Cb' and Cc' are arranged in this order.
- the cams Ca', Cb' and Cc' have a cam profile different from each other.
- the cam profiles of the cams Ca' and Cb' are set so that the exhaust valve 55 is driven in at least an exhaust stroke of the exhaust stroke and an inlet stroke.
- the cam profiles of the cams Ca' and Cb' is set so that an opening period of the exhaust valve 55 according to the cam Ca' includes an opening period of the exhaust valve 55 according to the cam Cb', and a lift amount of the exhaust valve 55 caused by the cam Ca' is larger than that by the cam Cb'.
- the cam profile of the cam Cc' is set so that the exhaust valve 55 is driven at a timing that is different from the cams Ca' and Cb'.
- the cam profile of the cam Cc' is set so that the exhaust valve 55 opens during opening period of the inlet valve 54.
- the cam Cc' is used together with the cam Cb'.
- the cam Cc' is used together with the cam Ca'.
- the variable operated-valve structure 60' has a locker arm portion 63' and a hydraulic type linking structures 631'and 632'.
- the locker arm portion 63' individually oscillates in accordance with the cam profiles of the cams Ca', Cb' and Cc', and has oscillation portions 63a', 63b' and 63c' mediating driving force to the exhaust valve 55 from the camshaft 65'.
- the oscillation portion 63a' has a cam-contact portion 61a'.
- the oscillation portion 63b' has a cam-contact portion 61b'.
- the oscillation portion 63c' has a cam-contact portion 61c'.
- the cam-contact portion 61a' is a cam-contact portion contacting the cam Ca' of the plurality of the cam-contact portions 61'.
- the cam-contact portion 61b' is a cam-contact portion contacting the cam Cb'.
- the cam-contact portion 61c' is a cam-contact portion contacting the cam Cc'.
- the linking structures 631' and 632' perform linking and canceling the linking with the same mechanism as the linking structures 631 and 632. Therefore, a description of a concrete structure of the linking structures 631' and 632' is omitted.
- the OCV 81' is connected to the linking structure 631'.
- the OCV 82' is connected to the linking structure 632'.
- the OCV 81' conducts the hydraulic pressure P in to the linking structure 631'.
- the OCV 81' is off, the OCV 81' releases the hydraulic pressure from the linking structure 631'.
- the OCV 82' When the OCV 82' is on, the OCV 82' conducts the hydraulic pressure P in to the linking structure 632'.
- the OCV 82' releases the hydraulic pressure from the linking structure 632'.
- the linking structure 631' links between the oscillation portions 63a' and 63b' when the OCV 81' is on.
- the hydraulic pressure P in conducted via the OCV 81' moves pins Pn11' and Pn12' against the biasing force of a spring Spl'.
- the oscillation portions 63a'and 63b' are linked.
- the linking structure 631' cancels the linking between the oscillation portions 63a' and 63b' when the OCV 81' is off.
- the spring Sp1' moves the pins Pn11' and Pn12' against the hydraulic pressure released via the OCV 81'.
- the linking structure 631' performs linking and canceling the linking between the oscillation portions 63a' and 63b' with the pin Pn11'.
- the linking structure 632' performs linking and canceling the linking between the oscillation portions 63b' and 63c' with the pin Pn21', as in the case of the linking structure 631'. Therefore, the linking structures 631' and 632' perform linking and canceling the linking between two of the oscillation portions 63a', 63b' and 63c' with the pin Pn11' or the pin Pn21'.
- the oscillation portion 63b' has the valve drive portion 62'. Therefore, in the variable operated-valve structure 60', the oscillation portion 63b' of the oscillation portions 63a', 63b' and 63c' drives the exhaust valve 55.
- the usage patterns of the usage cam realized by the variable operated-valve structure 60' are as follows.
- FIG. 14A to FIG. 14C illustrate a usage pattern of the usage cam.
- FIG. 14A illustrates the first pattern.
- FIG. 14B illustrates the second pattern.
- FIG. 14C illustrates the third pattern.
- the oscillation portions 63a' and 63c' illustrated with a broken line are under a condition that linking is canceled.
- the cam Ca' is used.
- the linking structure 631' links between the oscillation portions 63a' and 63b', and the linking structure 632' cancels the linking between the oscillation portions 63b' and 63c'.
- the exhaust valve 55 can be driven according to the cams Ca' and Cb'.
- the cam profiles of the cams Ca' and Cb' are set so that the lift amount of the exhaust valve 55 caused by the cam Ca' is larger than that by the cam Cb' in each phase, as mentioned above. Therefore, in this case, the exhaust valve 55 is driven according to the cam Ca'.
- the cam Cb' is the usage cam.
- the linking structure 631' cancels the linking between the oscillation portions 63a' and 63b'
- the linking structure 632' cancels the linking between the oscillation portions 63b' and 63c'.
- the driving force is not conducted from the oscillation portion 63a' to the oscillation portion 63b'.
- the driving force is not conducted from the oscillation portion 63c' to the oscillation portion 63b'. Therefore, in this case, the exhaust valve 55 is driven according to the cam Cb'.
- the cams Cb' and Cc' are the usage cam.
- the linking structure 631' cancels the linking between the oscillation portions 63a' and 63b', and the linking structure 632' links between the oscillation portions 63b' and 63c'.
- the exhaust valve 55 is driven according to the cams Cb' and Cc'.
- FIG. 15 illustrates a determination method based on the hydraulic pressure P3 in the variable operated-valve structure 60'.
- FIG. 15A illustrates the changing of the hydraulic pressure P3 when the cam Ca' is the usage cam.
- FIG. 15B illustrates the changing of the hydraulic pressure P3 when the cam Cb' is the usage cam.
- FIG. 15C illustrates the changing of the hydraulic pressure P3 when the cams Cb' and Cc' are the usage cam.
- FIG. 15D illustrates lift curved lines La', Lb' and Lc' according to the cams Ca', Cb' and Cc'. In FIG. 15A to FIG. 15D , the crank angle of the horizontal axis is common.
- the oil path R3 is provided as follows in a viewpoint of improving of the determination accuracy. That is, the oil path R3 is provided so that the hydraulic pressure P3 is reduced when the difference between the oscillation portions 63b' and 63c' is larger than the difference between the oscillation portions 63a' and 63b'. Therefore, the reduction period of the hydraulic pressure P3 in a case where there is a difference between the oscillation portions 63a' and 63b' is longer than that in a case where there is a difference between the oscillation portions 63b' and 63c'.
- the linking structure 631' links between the oscillation portions 63a' and 63b' and the linking structure 632' cancels the linking between the oscillation portions 63b' and 63c'. Therefore, in this case, the oscillation portions 63a' and 63b' integrally oscillate in accordance with the cam Ca'.
- the oscillation portion 63c' oscillates in accordance with the cam Cc'. In this case, when there is a difference between the oscillation direction of the oscillation portions 63a' and 63b' and the oscillation direction of the oscillation portion 63c', the oil path R3 is closed. As a result, as illustrated in FIG. 15A , when there is a difference between the oscillation direction of the oscillation portion 63b' and 63c', the hydraulic pressure P3 is reduced.
- the linking structure 631' cancels the linking between the oscillation portions 63a' and 63b'
- the linking structure 632' cancels the linking between the oscillation portions 63b' and 63c'. Therefore, in this case, the oscillation portion 63a'oscillates in accordance with the cam Ca', the oscillation portion 63b' oscillates in accordance with the cam Cb', and the oscillation portion 63c' oscillates in accordance with the cam Cc'.
- the oil path R3 is closed.
- the linking structure 631' cancels the linking between the oscillation portions 63a' and 63b', and the linking structure 632' links between the oscillation portions 63b' and 63c'. Therefore, in this case, the oscillation portion 63a' oscillates in accordance with the cam Ca'.
- the oscillation portions 63b' and 63c' integrally oscillate in accordance with the cams Cb' and Cc'. In this case, when there is a difference between the oscillation directions between the oscillation portions 63a' and 63b', the oil path R3 is closed. As a result, as illustrated in FIG. 15C , when there is a difference between the oscillation portions 63a' and 63b', the hydraulic pressure P3 is reduced.
- the determination unit can determine the switching phase of the usage cam (in concrete, the usage cam) based on the reduction condition of the hydraulic pressure P3.
- the case where the cams Ca' and Cc' are the usage cam is excluded from the usage pattern. However, in this case, it is possible to determine that the cams Ca' and Cc' are the usage cam when the hydraulic pressure P3 is not reduced.
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- Valve Device For Special Equipments (AREA)
- Output Control And Ontrol Of Special Type Engine (AREA)
Description
- The present invention relates to an internal combustion engine such as known from
EP0297791 A1 . - There is known a technology in which a condition of a usage cam switched by a cam-switching type variable operated-valve structure is determined.
Patent Document 1 discloses a variable operated-valve structure of an internal combustion engine having an operation determination means that detects an operation hydraulic pressure and determines operation condition of a variable valve lift structure based on a detected hydraulic pressure.Patent Document 1 discloses that a usage time of a low-speed cam and a usage time of a high-speed cam by comparing the operation hydraulic pressure with a predetermined value. - PTL 1: Japanese Patent Application Publication No.
8-74537 - Recently, a technology in which a switch timing of a usage cam by a variable operated-valve structure is determined with high accuracy is demanded. However, even if the operation hydraulic pressure is compared with the predetermined value as in the case of
Patent Document 1, it is possible that the switch timing of the usage cam cannot be determined with high accuracy. As a result, it is not possible to consider abnormality of the switch timing caused by defect of sliding of a lock member. Alternately, even if the operation hydraulic pressure is compared with the predetermined value, many hydraulic sensors are needed in an internal combustion engine having a plurality of cylinders. Therefore, the structure may be disadvantageous in cost and mounting. - Therefore, the present invention has an object to provide an internal combustion engine that is callable of preferably determining a switching phase of a usage cam by a variable operated-valve structure.
- An internal combustion engine includes: a plurality of cams that are used for driving a valve; a cam-switching type variable operated-valve structure that has a locker arm portion and a plurality of hydraulic linking structures, the locker arm portion having a plurality of oscillation portions that individually oscillate according to cam profiles of the cams and mediate power conducted from a camshaft having the cams to the valve, the plurality of linking structures performing linking and canceling the linking between two of the plurality of oscillation portions with a lock member, the variable operated-valve structure selecting a usage cam that is used for driving the valve from the cams; and a determination unit that determines at least one of a condition of the lock member and a switching phase of the usage cam according to the condition of the lock member based on changing of a hydraulic pressure according to the switching of the usage cam.
- The determination unit may determine termination of an operation of the lock member in a linking structure of the plurality of linking structures that performs linking or canceling the linking during the switching of the usage cam based on a value and changing width of a hydraulic pressure detected and stored when the valve does not perform lifting, the hydraulic pressure changing according to a movement of the lock member in the linking structure of the plurality of linking structures that performs linking or cancelling the linking.
- The variable operated-valve structure may have an oil path that penetrates the plurality of oscillation portions under a condition that the valve does not perform lifting; and the determination unit may determine the usage cam based on a reduction condition of a hydraulic pressure conducted by the oil path including with or without reduction of the hydraulic pressure.
- The variable operated-valve structure may be provided at least one of on an inlet side and on an exhaust side and has a plurality of the locker arm portions that are respectively provided in each of a plurality of cylinders; the locker arm portions may share the oil path among the plurality of cylinders at least one of on the inlet side and on the exhaust side, or the locker arm portions share the oil path among the plurality of cylinders both on the inlet side and on the exhaust side; and the variable operated-valve structure may share the oil path between the inlet side and the exhaust side.
- The oil path also may act as a lubricant oil path to supply oil for lubrication.
- The oil path may be different from an oil path to supply a hydraulic pressure to the plurality of linking structures.
- According to an aspect of the present invention, it is possible to preferably determine a switching phase of a usage cam by a variable operated-valve.
-
- [
fig.1]FIG. 1 illustrates an overall structure diagram of an internal combustion engine and around the internal combustion engine; - [
fig.2]FIG. 2 illustrates a schematic structure diagram of an internal combustion engine; - [
fig.3]FIG. 3 illustrates a schematic structure of a variable operated-valve structure; - [
fig.4]FIG. 4 illustrates a linking structure; - [
fig.5]FIG. 5A to FIG. 5C illustrate phases of cam switching; - [
fig.6]FIG. 6 illustrates a determination; - [
fig.7]FIG. 7 illustrates an example of a flowchart of a first condition; - [
fig.8]FIG. 8 illustrates a variable operated-valve structure unit of a second embodiment; - [
fig.9]FIG. 9A to FIG. 9D illustrate a determination method in accordance with a second embodiment; - [
fig.10]FIG. 10 illustrates an example of a flowchart of a second embodiment; - [
fig.11]FIG. 11 is a first drawing of a main part of another variable operated-valve structure; - [
fig.12]FIG. 12 is a second drawing of a main part of another variable operated-valve structure; - [
fig.13]FIG. 13A and FIG. 13B illustrate another camshaft; - [
fig.14]FIG. 14A to FIG. 14C illustrate a usage patterns of usage cam of another example; and - [
fig.15]FIG. 15A to FIG. 15D illustrates another determination method. - A description will be given of embodiments with reference to drawings.
-
FIG. 1 illustrates an overall structure diagram of aninternal combustion engine 50A and around theinternal combustion engine 50A.FIG. 2 illustrates a schematic structure diagram of theinternal combustion engine 50A.FIG. 3 illustrates a schematic structure of a variable operated-valve structure 60A.FIG. 3 illustrates the variable operated-valve structure 60A together with acamshaft 65. Theinternal combustion engine 50A is an internal combustion engine of a compression ignition type, and has a plurality of (four in this case)cylinders 51a. Theinternal combustion engine 50A is mounted on a vehicle not illustrated together with aninlet system 10, anexhaust system 20 and anexhaust reflux system 40. Theinternal combustion engine 50A may be an internal combustion engine of a spark ignition type. - The
inlet system 10 has anair flow meter 11, anintercooler 12 and anintake manifold 13. Theair flow meter 11 measures an intake air amount. Theintercooler 12 cools the intake air. Theintake manifold 13 distributes the intake air into eachcylinder 51a of theinternal combustion engine 50A. - The
exhaust system 20 has anexhaust manifold 21 and acatalyst 22. Theexhaust manifold 21 converges exhausted air from eachcylinder 51a. Thecatalyst 22 cleans up the exhausted air. Asupercharger 30 is provided in theinlet system 10 and theexhaust system 20. Thesupercharger 30 supercharges intake air to theinternal combustion engine 50A. - The
exhaust reflux system 40 has anEGR pipe 41, anEGR cooler 42 and anEGR valve 43. TheEGR pipe 41 communicates theinlet system 10 with theexhaust system 20. In concrete, theEGR pipe 41 communicates a pathway-assembly portion of theintake manifold 13 with another pathway-assembly portion of theexhaust manifold 21. TheEGR cooler 42 cools the refluxed exhaust air. TheEGR valve 43 adjusts an amount of the refluxed exhaust air. - The
internal combustion engine 50A has acylinder block 51, acylinder head 52, apiston 53, aninlet valve 54, anexhaust valve 55, afuel injection valve 56, a variable operated-valve structure 60A and acamshaft 65, in addition to theECU 70A. Thepiston 53, theinlet valve 54, theexhaust valve 55, and thefuel injection valve 56 are provided in eachcylinder 51a. Thecylinder block 51 has thecylinder 51a. Thecylinder 51a houses thepiston 53. Thecylinder head 52 is fixed to an upper face of thecylinder block 51. A combustion chamber E is a space surrounded by thecylinder block 51, thecylinder head 52 and thepiston 53. Thepiston 53 is adjacent to the combustion chamber E. - The
cylinder head 52 has aninlet port 52a guiding inlet air to the combustion chamber E and anexhaust port 52b exhausting gas from the combustion chamber E. And, thecylinder head 52 has aninlet valve 54 opening or closing theinlet port 52a and anexhaust valve 55 opening or closing theexhaust port 52b. In concrete, a plurality of (two)inlet valves 54 and a plurality of (two)exhaust valves 55 are provided in eachcylinder 51a. Thefuel injection valve 56 is provided in thecylinder head 52 and injects fuel to the combustion chamber E. - The variable operated-
valve structure 60A is provided in thecylinder head 52. The variable operated-valve structure 60A is a cam-switch type variable operated-valve structure, and selects a usage cam used for driving theinlet valve 54 from a first cam Ca, a second cam Cb and a third cam Cc. The cams Ca, Cb and Cc are provided on thecamshaft 65 and form a plurality of cam used for driving theinlet valve 54. The number of the plurality of the cams may be three or more. - In concrete, the cams Ca, Cb and Cc are respectively provided in each
cylinder 51a. Therefore, the cams Ca, Cb and Cc are used for driving theinlet valve 54 in eachcylinder 51a. The variable operated-valve structure 60A selects a usage cam used for driving theinlet valve 54 from the cams Ca, Cb and Cc in eachcylinder 51a. - The variable operated-
valve structure 60A has a cam-contact portion 61, avalve drive portion 62, alocker arm portion 63 and alocker arm shaft 64. The cam-contact portion 61, thevalve drive portion 62 and thelocker arm portion 63 are provided in eachcylinder 51a and form a unit U. - The cam-
contact portion 61 is a cam follower. A plurality of (three) cam-contact portions 61 are respectively provided in the cams Ca, Cb and Cc. A cam-contact portion 61a is a cam-contact-portion contacting the cam Ca in the cam-contact portion 61. A cam-contact portion 61b is a cam-contact portion contacting the cam Cb. A cam-contact portion 61c is a cam-contact portion contacting the cam Cc. A plurality of the cam-contact portions 61 are respectively provided in thelocker arm portion 63. - The
valve drive portion 62 is provided in thelocker arm portion 63. The number of the valve drive portion 62 (two) is the same as that of theinlet valve 54 provided in eachcylinder 51a. Thevalve drive portion 62 conducts driving force to theinlet valve 54. A screw tappet may be applied to thevalve drive portion 62. Thevalve drive portion 62 may be a part of thelocker arm portion 63. - The
locker arm portion 63 is driving-force mediation portion and mediates driving force conducted from thecamshaft 65 to theinlet valve 54 together with the cam-contact portion 61 and thevalve drive portion 62. Thelocker arm shaft 64 is inserted into thelocker arm portion 63. Thelocker arm shaft 64 supports thelocker arm portion 63 so that thelocker arm portion 63 can slide. Thelocker arm shaft 64 is a common shaft in the units U provided in eachcylinder 51a. Thelocker arm shaft 64 extends along an extending direction of thecamshaft 65. - The
locker arm portion 63 has anoscillation portions oscillation portions camshaft 65 in this order. Theoscillation portions camshaft 65 to theinlet valve 54. - The
oscillation portion 63a acting as a first oscillation portion has a cam-contact portion 61a. Therefore, theoscillation portion 63a oscillates according to the cam Ca. Theoscillation portion 63b acting as a second oscillation portion has the cam-contact portion 61b. Theoscillation portion 63c acting as a third oscillation portion has the cam-contact portion 61c. Therefore, theoscillation portion 63b oscillates according to the cam Cb. Theoscillation portion 63c oscillates according to the cam Cc. - The
valve drive portion 62 is provided in theoscillation portion 63b and theoscillation portion 63c. Therefore, in thelocker arm portion 63, theoscillation portions oscillation portions inlet valve 54. Theoscillation portions locker arm shaft 64 so that theoscillation portions - The
locker arm portion 63 has a linkingstructures structures oscillation portions structure 631 acting as a first linking structure links between theoscillation portions structure 632 acting as a second linking structure links between theoscillation portions structure 632 performs linking and canceling the linking between theoscillation portions - The
oscillation portion 63a has a biasing member such as a return spring that biases the cam-contact portion 61a toward the cam Ca so that the cam Ca is capable of driving theinlet valve 54. Therefore, theoscillation portion 63a makes the cam-contact portion 61a contact the cam Ca under a condition that the linking is canceled. -
FIG. 4 illustrates the linkingstructures structure 631 has a support portions H11 and H12 and pins Pn11 and Pn12, and a spring Sp1. Theoscillation portion 63b has the support portion H11. Theoscillation portion 63c has the support portion H12. The support portions H11 and H12 are arranged along an extending direction of thecamshaft 65 when theinlet valve 54 does not perform lifting. The support portions H11 and H12 have a cylinder shape having a bottom and have an identical inner diameter. The "identical" includes a case where the diameters are different from each other within a production error. The same shall apply hereafter. - The pin Pn11 is at least supported by the support portion H11 of the support portions H11 and H12. The pin Pn12 is at least supported by the support portion H12 of the support portions H11 and H12. The pins Pn11 and Pn12 have a cylinder shape and have an identical outer diameter. The outer diameter of the pins Pn11 and
Pn 12 is smaller than the inner diameter of the support portions H11 and H12 by a clearance for sliding. - A spring chamber G11 is formed between a bottom of the support portion H11 and the pin Pn11. The spring chamber G11 is a hydraulic chamber. A hydraulic chamber G12 is formed between a bottom of the support portion H12 and the
pin Pn 12. The spring Sp1 is provided in the spring chamber G11. The spring Sp1 biases the pin Pn11. - An OCV (Oil Control Valve) 81 is connected to the linking
structure 631. TheOCV 81 is connected to the spring chamber G11 via an oil path R11, and is connected to the hydraulic chamber G12 via an oil path R12. TheOCV 81 releases the hydraulic pressure from the hydraulic chamber G12 and conducts a hydraulic pressure Pin to the spring chamber G11, when theOCV 81 is off. TheOCV 81 conducts the hydraulic pressure Pin to the hydraulic chamber G12 and releases the hydraulic pressure from the spring chamber G11, when theOCV 81 is on. The hydraulic pressure Pin is common supplied hydraulic pressure to the linkingstructures structures OCVs - The linking
structure 631 links between theoscillation portions OCV 81 is off. In concrete, in this case, under a condition that theinlet valve 54 does not perform the lifting, the hydraulic pressure Pin conducted to the spring chamber G11 via a spring Sp1 and theOCV 81 moves the pins Pn11 and Pn12 against the hydraulic pressure released from the hydraulic chamber G12 via theOCV 81. As a result, when the oscillation portions H11 and H12 support the pin Pn11, theoscillation portions OCV 81 is off, the linkingstructure 631 can link between theoscillation portions - When the
OCV 81 is on, the linkingstructure 631 cancels the linking between theoscillation portions inlet valve 54 does not perform the lifting, the hydraulic pressure Pin conducted to the hydraulic chamber G12 via theOCV 81 moves the pins Pn11 and Pn12 against the hydraulic pressure released from the spring chamber G11 via theOCV 81. As a result, when the pin Pn11 is supported by the support portion H11, the linking between theoscillation portions - In concrete, the linking
structure 632 has a support portions H21, H22 and H23, pins Pn21, Pn22 and Pn23, and a spring Sp2. Theoscillation portion 63b has the support portion H21. Theoscillation portion 63a has the support portion H22. Theoscillation portion 63c has the support portion H23. The support portions H21, H22 and H23 are arranged along an extending direction of thecamshaft 65 when theinlet valve 54 does not perform the lifting. The support portions H21 and H23 have a cylinder shape having a bottom. The support portion H22 has a cylinder shape. The support portions H21, H22 and H23 have an identical inner diameter. - The pin Pn21 is at least supported by the support portion H21 of the support portions H21 and H22. The pin Pn22 is at least supported by the support portion H22 of the support portions H22 and H23. The pin Pn23 is supported by the support portion H23. The pins Pn21, Pn22 and Pn23 have a cylinder shape and have an identical outer diameter. The outer diameter of the pins Pn21, Pn22 and Pn23 is smaller than the inner diameter of the support portions H21, H22 and H23 by a clearance for sliding.
- A hydraulic chamber G21 is formed between a bottom of the support portion H21 and the pin Pn21. A spring chamber G22 is formed between a bottom of the support portion H23 and the pin Pn23. The spring Sp2 is provided in the spring chamber G22. The spring Sp2 biases the pin Pn23. The
OCV 82 is connected to the linkingstructure 632. TheOCV 82 is connected to the hydraulic chamber G21 via an oil path R2. TheOCV 82 conducts the hydraulic pressure Pin to the hydraulic chamber G21 when theOCV 82 is on. TheOCV 82 releases the hydraulic pressure Pin from the hydraulic chamber G21 when theOCV 82 is off. - The linking
structure 632 links between theoscillation portions OCV 82 is on. In concrete, in this case, under a condition that theinlet valve 54 does not perform the lifting, the hydraulic pressure Pin conducted to the hydraulic chamber G21 via theOCV 82 moves the pins Pn21, Pn22 and Pn23 against the biasing force of the spring Sp2. As a result, when the pin Pn22 is supported by the support portions H22 and H23, theoscillation portions OCV 82 is on, the linkingstructure 632 links between theoscillation portions oscillation portions - When the
OCV 82 is off, the linkingstructure 632 cancels the linking between theoscillation portions inlet valve 54 does not perform the lifting, the spring Sp2 moves the pins Pn21, Pn22 and Pn23 against the hydraulic pressure released from the hydraulic chamber G21 via theOCV 82. As a result, when the pin Pn21 is supported by the support portion H21 and the pin Pn22 is supported by the support portion H22, the linking between theoscillation portions OCV 82 is off, the linkingstructure 632 cancels the linking between theoscillation portions oscillation portions - In this manner, in concrete, in the linking
structure 631, the pin Pn11 links between theoscillation portions structure 632, the pin Pn22 links between theoscillation portions pin Pn 11 acts a first lock member. The pin Pn22 acts as a second lock member. In the linkingstructure 632, the pin Pn21 linking between theoscillation portions structure 632, at least one of the pins Pn21 and Pn22 may act as the lock member. The oil paths R11, R12 and R2 may be provided according to a linking structure of the linkingstructures locker arm shaft 64. -
FIG. 5A to FIG. 5C illustrate phases of cam switching phase.FIG. 5A illustrates a phase where the cam Cb is the usage cam.FIG. 5B illustrates a phase where the cam Cb is the usage cam.FIG. 5C illustrates a phase where the cam Cc is the usage cam. InFIG. 5A to FIG. 5C , thecamshaft 65 and the lift curved-lines La, Lb and Lc are illustrated together with the unit U. The lift curved-line La is a curved line obtained in a case where theinlet valve 54 is driven in accordance with the cam profile of the cam Ca. The lift curved-line Lb is a curved line obtained in a case where theinlet valve 54 is driven in accordance with the cam profile of the cam Cb. The lift curved-line Lc is a curved line obtained in a case where theinlet valve 54 is driven in accordance with the cam profile of the cam Cc. - As illustrated in
FIG. 5A , the variable operated-valve structure 60A may use the cam Cb as the usage cam when the linkingstructure 631 links between theoscillation portions structure 632 cancels the linking between theoscillation portions oscillation portions FIG. 5B , the cams Cb and Cc may be used as the usage cam when the linkingstructure 631 cancels the linking between theoscillation portions structure 632 cancels the linking between theoscillation portions oscillation portions FIG. 5C , the cam Ca may be used as the usage cam when the linkingstructure 631 links between theoscillation portions structure 632 links between theoscillation portions oscillation portions - The cams Ca, Cb and Cc are arranged along an extending direction of the
camshaft 65 in this order. The cams Ca, Cb and Cc have a different cam profile. As indicated by the lift curved-lines La, Lb and Lc, the cam profiles of the cams Ca, Cb and Cc are set so that a lift amount of theinlet valve 54 caused by the cam Ca is more than that by the cam Cb, and the amount caused by the cam Cb is more than that by the cam Cc. In other words, the cam profiles of the cams Ca, Cb and Cc are set so that the lift curved-line Lb is included in the lift curved-line La, and the lift curved-line Lc is included in the Lift curved-line Lb. - The variable operated-
valve structure 60A has a plurality of modes as a cam switching mode. The cam switching mode is distinguished with respect to each switching phase of a usage cam. The switching phase of the usage cam can be specified by a switching from one of two usage patterns of a plurality of usage patterns to the other. The usage pattern of the usage cam includes a first pattern using the cam Cb as the usage cam, a second pattern using the cams Cb and Cc as the usage cam, and a third pattern using the cam Ca as the usage cam. - The cam switching mode includes the following first to third modes. The first mode is a mode in which the switching phase of the usage cam is a switching from the cam Cb to the cams Cb and Cc. The second mode is a mode in which the switching phase of the usage cam is a switching from the cam Cb to the cam Ca. The third mode is a mode in which the switching phase of the usage cam is a switching from the cams Cb and Cc to the cam Ca. A plurality of modes that the variable operated-
valve structure 60A has as a cam switching mode are the first to third modes and fourth to sixth modes of which mode is opposite to the first to third modes. - The
ECU 70A illustrated inFIG. 1 and so on is an electronic control device. TheEGR valve 43, thefuel injection valve 56, theOCVs ECU 70A as a controlled object. Theair flow meter 11, acrank angle sensor 91 to detect a crank angle q, anaccelerator position sensor 92 to request acceleration to theinternal combustion engine 50A, and ahydraulic sensors ECU 70A as a sensor-switch portion. The hydraulic pressure P1 is a hydraulic pressure in the spring chamber G11. The hydraulic pressure P2 is a hydraulic pressure in the hydraulic chamber G21. The hydraulic pressure P1 can be detected via an oil path for detecting hydraulic pressure from the spring chamber G11. The hydraulic pressure P2 can be detected via the oil path from the hydraulic chamber G21. TheECU 70A detects a rotation number Ne that is an engine rotation number based on an output of thecrank angle sensor 91. - When a CPU executes processes with use of a temporary storage area of a RAM as necessary based on a program stored in a ROM, for example, a determination unit and a decision unit are realized in the
ECU 70A. The units may be realized in a plurality of electronic control devices. - The determination unit determines a condition of a pin acting as a lock member (in concrete, at least one of the pins Pn11 and Pn22) based on the changing of the hydraulic pressure caused by the switching of the usage cam. In concrete, the determination unit determines the condition of the pin acting as the lock member based on the hydraulic pressure (hereinafter referred to as object hydraulic pressure) changing according to a movement of the pin acting as the lock member when the
inlet valve 54 does not perform the lifting in the linking structure performing linking or canceling the linking of the linkingstructures - The decision unit decides at least one of the hydraulic pressures P1 and P2 as the object hydraulic pressure based on the cam switching mode. The object hydraulic pressure may be specified from the hydraulic pressures P1 and P2 in advance in accordance with the cam switching mode. The object hydraulic pressure is a hydraulic pressure detected with a time element. In concrete, the object hydraulic pressure may be hydraulic pressure obtained according to the crank angle q or the like.
- The determination unit determines the condition of the pin Pn11 based on the hydraulic pressure P1 when the object hydraulic pressure is the hydraulic pressure P1. The determination unit determines the condition of the pin Pn22 based on the hydraulic pressure P2 when the object hydraulic pressure is the hydraulic pressure P2. The determinations unit determines the conditions of the pins Pn11 and Pn21 when the object hydraulic pressure is the hydraulic pressures P1 and P2.
- In concrete, the determination unit performs a first determination whether an object pin is operated (operation starts). The object pin is a pin acting as the lock member in the linking structure performing linking or canceling the linking during switching the usage cam of the linking
structures inlet valve 54 does not perform the lifting. -
FIG. 6 illustrates the determination.FIG. 6 illustrates an example of the changing of the object hydraulic pressure during the switching of the usage cam together with the lift amount of theinlet valve 54 and on and off of theOCV 81. InFIG. 6 , the object hydraulic pressure and the on and off of theOCV 81 are illustrated with a solid line, and the lift amount of theinlet valve 54 is illustrated with a broken line.FIG. 6 illustrates a case where the cam switching mode is the fourth mode (switching from the cams Cb and Cc to the cam Cb), and the object hydraulic pressure is the hydraulic pressure P1. InFIG. 6 , a hydraulic pressure P1' of the hydraulic chamber G12 is also illustrated. A predetermined value a1 is a value to detect a start of the changing of the object hydraulic pressure according to the switching of the usage cam. - In the first determination, the determination unit determines that the object pin operates when a difference between an initial value ini and a minimum value min of the object hydraulic pressure detected and stored when the
inlet valve 54 does not perform the lifting is more than a predetermined value a3. The period in which theinlet valve 54 does not perform the lifting is a base circle section. The base circle section is a section in which a base circle portion of the usage cam decides the lift amount of theinlet valve 54. The predetermined value a3 is a value for detecting pressure changing (in concrete, decrease of pressure) occurred by starting of the movement of the objective pin. - In this manner, the determination unit performing the first determination determines whether the object pin operates based on the changing at the starting of the operation of the object pin that is a changing of the hydraulic pressure caused by the switching of the usage cam. The determination unit determines whether the object pin locks by determining whether the object pin operates until a given time passes. The given time is a normal allowed time to terminate the switching of the usage cam.
- In the second determination, the determination unit determines whether the operation of the object pin is terminated based on a minimum value min and a changing width max-min of the objective hydraulic pressure detected and stored when the
inlet valve 54 does not perform the lifting. When the minimum value min is larger than a predetermined value a2 and the changing width max-min is less than a predetermined value b, the determination unit determines that the operation of the object pin is terminated. - The changing width max-min is a difference between the maximum value max and the minimum value min of the object hydraulic pressure. The predetermined value b is a value for determining whether the changing of the object hydraulic pressure converges. The predetermined value a2 is set so that the object hydraulic pressure does not pass after the operation of the object pin is terminated. In this manner, the determination unit performing the second determination determines the termination of the operation of the object pin based on the convergence of the hydraulic pressure changing according to the switching of the usage cam. In the second determination, the object hydraulic pressure can be stored with respect to each base circle section.
- Values of the predetermined values a1, a2, a3 and b may be different between a case where the object hydraulic pressure is the hydraulic pressure P1 and a case where the object hydraulic pressure is the hydraulic pressure P2. The values of the predetermined values a1, a2, a3 and b may be changed according to the hydraulic pressure Pin.
- The object hydraulic pressure may be a hydraulic pressure P1' acting as a back pressure instead of the hydraulic pressure P1 acting as a supply pressure. In this case, the determination unit may determine that the object pin operates when a difference between an initial value ini and a maximum value max of the hydraulic pressure P1' detected and stored when the
inlet valve 54 does not perform the lifting is larger than a predetermined value a3'. The determination unit may determine that the operation of the object pin is terminated when the maximum value max is less than a predetermined value a2' and a changing width max-min is less than a predetermined value b'. - The predetermined values a1', a2', a3'and b' may be set as in the case of the predetermined values a1, a2, a3 and b. The maximum value max corresponds to the value of the object hydraulic pressure in a case where the hydraulic pressure P1' is the object hydraulic pressure. Therefore, the value of the object hydraulic pressure may be the minimum value min when the object hydraulic pressure is the supply pressure, and the value of the object hydraulic pressure may be the maximum value max when the object hydraulic pressure is the back pressure. The determination unit may determine the condition of the pin acting as the lock member when a switching of the usage cam is requested.
- Next, a description will be given of an example of a first control performed by the
ECU 70A with reference to a flowchart ofFIG. 7. FIG. 7 illustrates a case where the switching of the usage cam is started in the fourth mode. The flowchart may start when the switching of the usage cam is requested. TheECU 70A detects the hydraulic pressure P1 (Step S1) and determines whether the detected hydraulic pressure P1 is more than the predetermined value a1 (Step S2). - When it is determined as "No" in the Step S2, the
ECU 70A activates a timer (Step S3) and determines whether a given time passes (Step S4). When it is determined as "No" in the Step S4, theStep 1 is executed again. When it is determined as "Yes" in the Step S4, the determination unit determines that theOVC 81 is abnormal (Step S5). After the Step S5, the Step S1 is executed again. After the Step S5, the flowchart may be terminated. - When it is determined as "Yes" in the Step S2, the
ECU 70A determines whether the current time is in the base circle section (Step S11). When it is determined as "Yes" in the Step S11, theECU 70A stores the hydraulic pressure P1[i] (Step S12). The hydraulic pressure P1[i] indicates the hydraulic pressure P1 of i-th base circle section. The number "i" is a number updated when the base circle section is transferred to a new base circle section. An initial value of the number "i" is one. After the Step S12, the Step S1 is executed again. In this case, the hydraulic pressure P1[i] is stored in the Step S12 until it is determined as "No" in the Step S11 in the routine after that. - When it is determined as "No" in the Step S11, the
ECU 70A determines whether a flag F is off (Step S21). The flag F is a flag for determining that the object pin operates. When it is determined as "Yes" in the Step S11, theECU 70A determines whether the difference between the initial value ini and the minimum value min of the stored hydraulic pressure P1[i] is larger than the predetermined value a3 (Step S22). When it is determined as "Yes" in the Step S22, theECU 70A determines that the pin operates and turns the flag on (Step S23). After the step S23,ECU 70A deletes the stored hydraulic pressure P1[i] (Step S29) and executes the Step S1 again. - When it is determined as "No" in the Step S22, the
ECU 70A determines whether a given time passes (Step S24). In the Step S24, theECU 70A determines based on whether the number "i" is larger than a threshold. The threshold may be determined by the engine operation condition. When it is determined as "Yes" in the Step S24, theECU 70A determines that the object pin locks (Step S25). After the Step S25, the Step S1 is executed again. After the Step S25, the flowchart is terminated. When it is determined as "No" in the Step S24, the Step S29 is executed. - When it is determined as "No" in the Step S21, the
ECU 70A determines whether the changing width max-min of the stored hydraulic pressure P1[i] is less than the predetermined value b (Step S26). When it is determined as "Yes" in the Step S21, theECU 70A determines whether the minimum value min of the hydraulic pressure P1[i] is larger than the predetermined value a2 (Step S27). When it is determined as "No" in the Step S26 or the Step S27, a Step S29 is executed. - When it is determined as "Yes" in the Step S26 or the Step S27, the
ECU 70A determines that the operation of the object pin is terminated (Step S28). After the Step S28, the Step S1 is executed again. After the Step S28, the flowchart may be terminated. - A description will be given of a main function and effect of the
internal combustion engine 50A. Theinternal combustion engine 50A can preferably determine the switching phase of the usage cam performed by the variable operated-valve structure 60A in view of determination accuracy, by determining the condition of the pin acting as the lock member based on the changing of the hydraulic pressure according to the switching of the usage cam. In concrete, theinternal combustion engine 50A can preferably determine the termination of the switching of the usage cam in a point of timing by determining the termination of the operation of the object pin based on the object hydraulic pressure and the changing width max-min that are detected and stored when theinlet valve 54 does not perform the lifting. - The
internal combustion engine 50A can determine the timing at the start of the operation of the object pin by determining whether the object pin operates based on the changing of the object pin at the starting of the operation that is the changing of the hydraulic pressure according to the switching of the usage cam. When it is determined whether the object pin operates until the predetermined time passes, it is possible to determine whether the object pin locks. - The
internal combustion engine 50A can determine whether the object pin operates by determining that the object pin operates in a case where the difference between the initial value ini and the minimum value min is larger than the predetermined value a3 when the object hydraulic pressure is the supply pressure and in a case where the difference between the initial value ini and the maximum value max is larger than the predetermined value a3' when the object hydraulic pressure is the back pressure, with respect to the object hydraulic pressure that is detected and stored when theinlet valve 54 does not perform the lifting. - An internal combustion engine in accordance with a second embodiment is substantially the same as the
internal combustion engine 50A illustrated inFIG. 2 except for the following points. The internal combustion engine in accordance with the second embodiment has another variable operated-valve structure hereinafter referred to as the variable operated-valve structure 60B) instead of the variable operated-valve structure 60A, and has another ECU (hereinafter referred to asECU 70B) instead of theECU 70A. The internal combustion engine in accordance with second the embodiment has another hydraulic sensor (hereinafter referred to as hydraulic sensor 95) instead of thehydraulic sensors FIG. 2 . The internal combustion engine in accordance with the second embodiment is hereinafter referred to as an internal combustion engine 50B. - The variable operated-valve structure 60B is substantially the same as the variable operated-
valve structure 60A except for a point that a unit U' described later is provided instead of the unit U. TheECU 70B is substantially the same as theECU 70A except for points that another determination unit is realized instead of the above-mentioned determination unit, the decision unit is not realized, thehydraulic sensor 95 is electrically coupled as a sensor-switch portion instead of thehydraulic sensors internal combustion engine 50A by changing the structure of theinternal combustion engine 50A. -
FIG. 8 illustrates the unit U'. The unit U' is substantially the same as the unit U expect for a point that the linkingstructures locker arm portion 63 with or without the oil path R3 is not distinguished by the numeral. InFIG. 8 , the oil paths R11, R12 and R2 are not illustrated. The oil path R3 is provided so as to penetrate theoscillation portions inlet valve 54 does not perform the lifting. Thelocker arm portion 63 shares the oil path R3 between the plurality ofcylinders 51a on the inlet side. The oil path R3 also acts as a lubricant oil path to supply oil for lubrication. The lubricant oil path is an oil path to supply oil to a lash adjuster. In the variable operated-valve structure 60B, thevalve drive portion 62 acts as the lash adjuster. - The oil path R3 has the
hydraulic sensor 95. Thehydraulic sensor 95 is provided on the downstream side compared to theoscillation portions hydraulic sensor 95 detects the hydraulic pressure P3 conducted by the oil path R3. The hydraulic pressure P3 is a hydraulic pressure conducted by the oil path R3 from theoscillation portions ECU 70B realizes the determination unit to determine the switching phase of the usage cam based on the hydraulic pressure P3. -
FIG. 9A to FIG. 9D illustrate a determination method based on the hydraulic pressure P3.FIG. 9A illustrates a changing of the hydraulic pressure P3 when the cam Ca is the usage cam.FIG. 9B illustrates the changing of the hydraulic pressure P3 when the cam Cb is the usage cam.FIG. 9C illustrates a changing of the hydraulic pressure P3 when the cams Cb and Cc are the usage cam.FIG. 9D illustrates lift curved lines La, Lb and Lc. InFIG. 9A to FIG. 9D , the crank angle of the horizontal axis is common. - When the cam Ca is the usage cam, the linking
structure 631 links between theoscillation portions structure 632 links between theoscillation portions oscillation portions FIG. 9A . - When the cam Cb is the usage cam, the linking
structure 631 links between theoscillation portions oscillation portions oscillation portions oscillation portion 63a oscillates in accordance with the cam Ca. In this case, when there is a difference between the oscillation direction of theoscillation portion 63a and the oscillation direction of theoscillation portions FIG. 9B , when there is a difference between the oscillation direction of theoscillation portion 63a and theoscillation portions - When the cams Cb and Cc are the usage cam, the linking
structure 631 cancels the linking between theoscillation portions oscillation portions oscillation portion 63a oscillates in accordance with the cam Ca, theoscillation portion 63b oscillates in accordance with the cam Cb, and theoscillation portion 63c oscillates in accordance with the cam Cc. In this case, when there is a difference between the oscillation directions of theoscillation portions oscillation portions FIG. 9C , when there is a difference between theoscillation portions oscillation portions - Therefore, the determination unit determines the switching phase of the usage cam according to the condition of the pin acting as the lock member based on the reduction condition of the hydraulic pressure P3 including with or without reduction. The reduction condition is a reduction period, for example. The reduction condition may be at least one of the reduction period, a reduction timing and a restoring timing of the hydraulic pressure P3. When the determination unit determines the switching phase of the usage cam, the determination unit determines which of the cams Ca, Cb and Cc the usage cam is. The determination unit determines the usage cam as the switching phase of the usage cam.
- Next, a description will be given an example of a second control performed by the
ECU 70B with reference to a flowchart ofFIG. 10 . TheECU 70B detects the hydraulic pressure P3 (Step S21), and determines whether the detected hydraulic pressure P3 is reduced (Step S22). When it is determined as "Yes" in the Step S22, theECU 70B starts measuring the reduction period of the hydraulic pressure P3 (Step S23). Next, theECU 70B determines whether the hydraulic pressure P3 is restored (Step S24). When it is determined as "No" in the Step S24, the Step S24 is executed again. - When it is determined as "Yes" in the Step S24, the
ECU 70B terminates the measuring of the reduction period of the hydraulic pressure P3 (Step S25), and determines whether the reduction period of the hydraulic pressure P3 is a predetermined period (reduction period of the hydraulic pressure P3 when the cam Cb is the usage cam) (Step S28). When it is determined as "No" in the Step S28, theECU 70B determines that the cams Cb and Cc are the usage cam (Step S29). After the Step S28 and the Step S29, the Step S21 is executed again. - When it is determined as "No" in the Step S22, the
ECU 70B determines whether there is reduction of the hydraulic pressure P3 during one combustion cycle (Step S27). When it is determined as "No" in the Step S27, the Step S21 is executed again. When it is determined as "Yes" in the Step S21, theECU 70B determines that the cam Ca is the usage cam (Step S30). After the Step S30, the Step S21 is executed again. - Next, a description will be given of a main function and effect of the internal combustion engine 50B. The internal combustion engine 50B determines the usage cam as the switching phase of the usage cam based on the reduction condition of the hydraulic pressure P3 including with or without the reduction. In this case, the internal combustion engine 50B can determine the switching phase of the usage cam by having the
hydraulic sensor 95 in the oil path R3. Therefore, the internal combustion engine 50B can preferably determine the switching phase of the usage cam in viewpoints of the cost or mounting. - The internal combustion engine 50B can determine the usage cam with a single
hydraulic sensor 95 with respect to eachcylinder 51a because the internal combustion engine 50B has a structure in which thelocker arm portion 63 shares the oil path R3 between the plurality ofcylinders 51a on the inlet side. That is, the internal combustion engine 50B can have the structure when preferably determining the switching phase of the usage cam in viewpoints of the cost and the mounting. - The internal combustion engine 50B prevents or suppresses size-growing of the
locker arm portion 63 for securing the oil path because the oil path R3 also acts as a lubricant oil path to supply oil for lubricant. It is preferable that the oil path R3 also acts as the lubricant oil path, in a point that no problem occurs because of the closing of the oil path R3 in accordance with the oscillation of theoscillation portions 63a to 63c even if the oil is supplied at an interval. - The present invention is not limited to the specifically disclosed embodiments and variations but may include other embodiments and variations without departing from the scope of the present invention.
- For example, in the above-mentioned embodiments, the valve is the
inlet valve 54. However, the valve may be an exhaust valve. The variable operated-valve structure may be provided on the inlet side and the exhaust side. In this case, on the inlet side and the exhaust side, the hydraulic sensor can be shared, when the locker arm portion shares an oil path corresponding to the oil path R3 between the plurality of cylinders on the inlet side and the exhaust side and the variable operated-valve structures share the oil path corresponding to the oil path R3 between the inlet side and the exhaust side. As a result, the structure has an advantage in cost. The variable operated-valve structure in a case where the valve is the exhaust valve is as follows. -
FIG. 11 is a first drawing of a main part of a variable operated-valve structure 60' that is another example.FIG. 12 is a second drawing of the main part of the variable operated-valve structure 60'.FIG. 13A and FIG. 13B illustrate a camshaft 65'.FIG. 13A illustrates an overall structure of the camshaft 65'.FIG. 13B illustrates a cross sectional view of cams Ca', Cb' and Cc' taken along a line A-A ofFIG. 13A .FIG. 11 illustrates the camshaft 65' and the variable operated-valve structure 60'.FIG. 12 illustrates the OCVs 81' and 82' and the variable operated-valve structure 60'. - The variable operated-valve structure 60' selects a usage cam for driving the
exhaust valve 55 from the cams Ca', Cb' and Cc'. The camshaft 65' has the cams Ca', Cb' and Cc'. The cams Ca', Cb' and Cc' act as a plurality of (three) cams used for driving theexhaust valve 55. The cams Ca', Cb' and Cc' are arranged in this order. - The cams Ca', Cb' and Cc' have a cam profile different from each other. The cam profiles of the cams Ca' and Cb' are set so that the
exhaust valve 55 is driven in at least an exhaust stroke of the exhaust stroke and an inlet stroke. In concrete, the cam profiles of the cams Ca' and Cb' is set so that an opening period of theexhaust valve 55 according to the cam Ca' includes an opening period of theexhaust valve 55 according to the cam Cb', and a lift amount of theexhaust valve 55 caused by the cam Ca' is larger than that by the cam Cb'. - The cam profile of the cam Cc' is set so that the
exhaust valve 55 is driven at a timing that is different from the cams Ca' and Cb'. The cam profile of the cam Cc' is set so that theexhaust valve 55 opens during opening period of theinlet valve 54. The cam Cc' is used together with the cam Cb'. The cam Cc' is used together with the cam Ca'. - The variable operated-valve structure 60' has a locker arm portion 63' and a hydraulic type linking structures 631'and 632'. The locker arm portion 63' individually oscillates in accordance with the cam profiles of the cams Ca', Cb' and Cc', and has
oscillation portions 63a', 63b' and 63c' mediating driving force to theexhaust valve 55 from the camshaft 65'. - The
oscillation portion 63a' has a cam-contact portion 61a'. Theoscillation portion 63b' has a cam-contact portion 61b'. Theoscillation portion 63c' has a cam-contact portion 61c'. The cam-contact portion 61a' is a cam-contact portion contacting the cam Ca' of the plurality of the cam-contact portions 61'. The cam-contact portion 61b' is a cam-contact portion contacting the cam Cb'. The cam-contact portion 61c' is a cam-contact portion contacting the cam Cc'. - The linking structures 631' and 632' perform linking and canceling the linking with the same mechanism as the linking
structures - The linking structure 631' links between the
oscillation portions 63a' and 63b' when the OCV 81' is on. In concrete, in this case, under a condition that theexhaust valve 55 does not perform the lifting, the hydraulic pressure Pin conducted via the OCV 81' moves pins Pn11' and Pn12' against the biasing force of a spring Spl'. As a result, when the pin Pn11' is supported by support portions H11' and H12', the oscillation portions 63a'and 63b' are linked. - The linking structure 631' cancels the linking between the
oscillation portions 63a' and 63b' when the OCV 81' is off. In concrete, in this case, under a condition that theexhaust valve 55 does not perform lifting, the spring Sp1' moves the pins Pn11' and Pn12' against the hydraulic pressure released via the OCV 81'. As a result, when the pin Pn11' is supported by the support portion H11', the linking between theoscillation portions 63a' and 63b' is canceled. Therefore, the linking structure 631' performs linking and canceling the linking between theoscillation portions 63a' and 63b' with the pin Pn11'. - The linking structure 632' performs linking and canceling the linking between the
oscillation portions 63b' and 63c' with the pin Pn21', as in the case of the linking structure 631'. Therefore, the linking structures 631' and 632' perform linking and canceling the linking between two of theoscillation portions 63a', 63b' and 63c' with the pin Pn11' or the pin Pn21'. - In the variable operated-valve structure 60', the
oscillation portion 63b' has the valve drive portion 62'. Therefore, in the variable operated-valve structure 60', theoscillation portion 63b' of theoscillation portions 63a', 63b' and 63c' drives theexhaust valve 55. The usage patterns of the usage cam realized by the variable operated-valve structure 60' are as follows. -
FIG. 14A to FIG. 14C illustrate a usage pattern of the usage cam.FIG. 14A illustrates the first pattern.FIG. 14B illustrates the second pattern.FIG. 14C illustrates the third pattern. Theoscillation portions 63a' and 63c' illustrated with a broken line are under a condition that linking is canceled. - In the first pattern, the cam Ca' is used. In this case, the linking structure 631' links between the
oscillation portions 63a' and 63b', and the linking structure 632' cancels the linking between theoscillation portions 63b' and 63c'. In this case, in the linking phase, theexhaust valve 55 can be driven according to the cams Ca' and Cb'. On the other hand, the cam profiles of the cams Ca' and Cb' are set so that the lift amount of theexhaust valve 55 caused by the cam Ca' is larger than that by the cam Cb' in each phase, as mentioned above. Therefore, in this case, theexhaust valve 55 is driven according to the cam Ca'. - In the second pattern, the cam Cb' is the usage cam. In this case, the linking structure 631' cancels the linking between the
oscillation portions 63a' and 63b', and the linking structure 632' cancels the linking between theoscillation portions 63b' and 63c'. In this case, the driving force is not conducted from theoscillation portion 63a' to theoscillation portion 63b'. Similarly, the driving force is not conducted from theoscillation portion 63c' to theoscillation portion 63b'. Therefore, in this case, theexhaust valve 55 is driven according to the cam Cb'. - In the third pattern, the cams Cb' and Cc' are the usage cam. In this case, the linking structure 631' cancels the linking between the
oscillation portions 63a' and 63b', and the linking structure 632' links between theoscillation portions 63b' and 63c'. As a result, theexhaust valve 55 is driven according to the cams Cb' and Cc'. -
FIG. 15 illustrates a determination method based on the hydraulic pressure P3 in the variable operated-valve structure 60'.FIG. 15A illustrates the changing of the hydraulic pressure P3 when the cam Ca' is the usage cam.FIG. 15B illustrates the changing of the hydraulic pressure P3 when the cam Cb' is the usage cam.FIG. 15C illustrates the changing of the hydraulic pressure P3 when the cams Cb' and Cc' are the usage cam.FIG. 15D illustrates lift curved lines La', Lb' and Lc' according to the cams Ca', Cb' and Cc'. InFIG. 15A to FIG. 15D , the crank angle of the horizontal axis is common. - In the variable operated-valve structure 60', the oil path R3 is provided as follows in a viewpoint of improving of the determination accuracy. That is, the oil path R3 is provided so that the hydraulic pressure P3 is reduced when the difference between the
oscillation portions 63b' and 63c' is larger than the difference between theoscillation portions 63a' and 63b'. Therefore, the reduction period of the hydraulic pressure P3 in a case where there is a difference between theoscillation portions 63a' and 63b' is longer than that in a case where there is a difference between theoscillation portions 63b' and 63c'. - When the cam Ca' is the usage cam, the linking structure 631' links between the
oscillation portions 63a' and 63b' and the linking structure 632' cancels the linking between theoscillation portions 63b' and 63c'. Therefore, in this case, theoscillation portions 63a' and 63b' integrally oscillate in accordance with the cam Ca'. On the other hand, theoscillation portion 63c' oscillates in accordance with the cam Cc'. In this case, when there is a difference between the oscillation direction of theoscillation portions 63a' and 63b' and the oscillation direction of theoscillation portion 63c', the oil path R3 is closed. As a result, as illustrated inFIG. 15A , when there is a difference between the oscillation direction of theoscillation portion 63b' and 63c', the hydraulic pressure P3 is reduced. - When the cam Cb' is the usage cam, the linking structure 631' cancels the linking between the
oscillation portions 63a' and 63b', and the linking structure 632' cancels the linking between theoscillation portions 63b' and 63c'. Therefore, in this case, the oscillation portion 63a'oscillates in accordance with the cam Ca', theoscillation portion 63b' oscillates in accordance with the cam Cb', and theoscillation portion 63c' oscillates in accordance with the cam Cc'. In this case, when there is a difference between the oscillation directions of theoscillation portions 63a' and 63b', the oil path R3 is closed. When there is a difference between the oscillation directions between theoscillation portions 63b' and 63c', the oil path R3 is closed. As a result, as illustrated inFIG. 15B , when there is a difference between theoscillation portions 63a' and 63b' and between theoscillation portions 63b' and 63c', the hydraulic pressure P3 is reduced. - When the cams Cb' and Cc' are the usage cam, the linking structure 631' cancels the linking between the
oscillation portions 63a' and 63b', and the linking structure 632' links between theoscillation portions 63b' and 63c'. Therefore, in this case, theoscillation portion 63a' oscillates in accordance with the cam Ca'. On the other hand, theoscillation portions 63b' and 63c' integrally oscillate in accordance with the cams Cb' and Cc'. In this case, when there is a difference between the oscillation directions between theoscillation portions 63a' and 63b', the oil path R3 is closed. As a result, as illustrated inFIG. 15C , when there is a difference between theoscillation portions 63a' and 63b', the hydraulic pressure P3 is reduced. - As illustrated in
FIG. 15A to FIG. 15C , the reduction condition of the hydraulic pressure P3 differs according to the usage cam. Therefore, in this case, the determination unit can determine the switching phase of the usage cam (in concrete, the usage cam) based on the reduction condition of the hydraulic pressure P3. The case where the cams Ca' and Cc' are the usage cam is excluded from the usage pattern. However, in this case, it is possible to determine that the cams Ca' and Cc' are the usage cam when the hydraulic pressure P3 is not reduced. -
- 50A, 50B
- internal combustion engine
- 54
- inlet valve
- 60A, 60B, 60'
- variable operated-valve structure
- 631, 631'
- linking structure (first linking structure)
- 632, 632'
- linking structure (second linking structure)
- 65, 65'
- camshaft
- 70A, 70B
- ECU
Claims (5)
- An internal combustion engine (50A) comprising:a plurality of cams (Ca, Cb, Cc) that are used for driving a valve (54);a cam-switching type variable operated-valve structure (60A) that has a rocker arm portion (63) and a plurality of hydraulic linking structures (631, 632), the rocker arm portion having a plurality of oscillation portions (63a, 63b, 63c) that individually oscillate according to cam profiles of the cams and mediate power conducted from a camshaft (65) having the cams to the valve, the plurality of linking structures performing linking and canceling the linking between two of the plurality of oscillation portions with a lock member (Pn11, Pn22), the variable operated-valve structure selecting a usage cam that is used for driving the valve from the cams; anda determination unit (70A) that determines at least one of a condition of the lock member and a switching phase of the usage cam according to the condition of the lock member based on changing of a hydraulic pressure according to the switching of the usage cam, characterized in thatthe determination unit determines termination of an operation of the lock member in a linking structure of the plurality of linking structures that performs linking or canceling the linking during the switching of the usage cam based on a value and changing width of a hydraulic pressure detected and stored when the valve does not perform lifting, the hydraulic pressure changing according to a movement of the lock member in the linking structure of the plurality of linking structures that performs linking or cancelling the linking.
- The internal combustion engine as claimed in claim 1, wherein:the variable operated-valve structure has an oil path (R3) that penetrates the plurality of oscillation portions under a condition that the valve does not perform lifting; andthe determination unit determines the usage cam based on a reduction condition of a hydraulic pressure conducted by the oil path including with or without reduction of the hydraulic pressure.
- The internal combustion engine as claimed in claim 2, wherein:the variable operated-valve structure is provided at least one of on an inlet side and on an exhaust side and has a plurality of the rocker arm portions that are respectively provided in each of a plurality of cylinders (51a);the rocker arm portions share the oil path among the plurality of cylinders at least one of on the inlet side and on the exhaust side, or the locker arm portions share the oil path among the plurality of cylinders both on the inlet side and on the exhaust side; andthe variable operated-valve structure shares the oil path between the inlet side and the exhaust side.
- The internal combustion engine as claimed in claim 2 or 3, wherein the oil path also acts as a lubricant oil path to supply oil for lubrication.
- The internal combustion engine as claimed in any of claims 2 to 4, wherein the oil path is different from an oil path (R11, R12, R2) to supply a hydraulic pressure to the plurality of linking structures.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2013212794A JP6237091B2 (en) | 2013-10-10 | 2013-10-10 | Internal combustion engine |
PCT/JP2014/005126 WO2015052930A1 (en) | 2013-10-10 | 2014-10-08 | Internal combustion engine |
Publications (2)
Publication Number | Publication Date |
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EP3055519A1 EP3055519A1 (en) | 2016-08-17 |
EP3055519B1 true EP3055519B1 (en) | 2017-07-12 |
Family
ID=51790829
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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EP14787299.8A Not-in-force EP3055519B1 (en) | 2013-10-10 | 2014-10-08 | Internal combustion engine |
Country Status (3)
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EP (1) | EP3055519B1 (en) |
JP (1) | JP6237091B2 (en) |
WO (1) | WO2015052930A1 (en) |
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Publication number | Priority date | Publication date | Assignee | Title |
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WO2018104872A1 (en) * | 2016-12-05 | 2018-06-14 | Eaton S.R.L. | Heavy duty variable valve actuation |
Family Cites Families (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS63147909A (en) * | 1986-10-23 | 1988-06-20 | Honda Motor Co Ltd | Valve operating state selector for internal combustion engine |
JPS643216A (en) * | 1987-06-25 | 1989-01-09 | Honda Motor Co Ltd | Valve system controller for internal combustion engine |
CA1331118C (en) * | 1988-10-11 | 1994-08-02 | Yasunari Seki | Failsafe method in connection with valve timing-changeover control for internal combustion engines |
JP2876538B2 (en) * | 1988-10-11 | 1999-03-31 | 本田技研工業株式会社 | Fail-safe processing method in valve timing switching control of internal combustion engine |
JP2723951B2 (en) * | 1989-02-06 | 1998-03-09 | 本田技研工業株式会社 | Valve operating state switching device for internal combustion engine |
JP2679836B2 (en) * | 1989-02-06 | 1997-11-19 | 本田技研工業株式会社 | Valve operating state switching device for internal combustion engine |
JP2703978B2 (en) * | 1989-02-23 | 1998-01-26 | 本田技研工業株式会社 | Valve train of internal combustion engine |
JPH02308912A (en) * | 1989-05-25 | 1990-12-21 | Honda Motor Co Ltd | Failure detecting device for valve timing switching control device of internal combustion engine |
DE69301140T2 (en) * | 1992-09-16 | 1996-05-15 | Honda Motor Co Ltd | Valve train arrangement for an internal combustion engine |
JP2668311B2 (en) * | 1992-09-16 | 1997-10-27 | 本田技研工業株式会社 | Valve train for internal combustion engine |
JP3293352B2 (en) | 1994-09-02 | 2002-06-17 | 日産自動車株式会社 | Variable valve train for internal combustion engines |
JP4286235B2 (en) * | 2005-04-20 | 2009-06-24 | 株式会社オティックス | Variable valve mechanism for internal combustion engine |
JP4542537B2 (en) * | 2006-11-14 | 2010-09-15 | 本田技研工業株式会社 | Variable valve gear |
-
2013
- 2013-10-10 JP JP2013212794A patent/JP6237091B2/en not_active Expired - Fee Related
-
2014
- 2014-10-08 WO PCT/JP2014/005126 patent/WO2015052930A1/en active Application Filing
- 2014-10-08 EP EP14787299.8A patent/EP3055519B1/en not_active Not-in-force
Also Published As
Publication number | Publication date |
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EP3055519A1 (en) | 2016-08-17 |
JP6237091B2 (en) | 2017-11-29 |
JP2015075053A (en) | 2015-04-20 |
WO2015052930A1 (en) | 2015-04-16 |
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