JP5793116B2 - Variable valve operating device for internal combustion engine - Google Patents

Description

  The present invention relates to a variable valve operating apparatus for an internal combustion engine that variably controls the operating characteristics of an engine valve that is an intake valve or an exhaust valve of the internal combustion engine.

  As a conventional variable valve operating device, for example, one described in Patent Document 1 below is known.

  Briefly, an inner cam shaft provided with two intake valves per cylinder, and an inner cam integrally driving the one intake valve on the outer periphery, and relatively rotatable on the outer periphery of the inner cam shaft. And an outer cam shaft integrally provided with an outer cam for driving the other intake valve on the outer periphery. Two vane type hydraulic actuators are integrally provided in series in the axial direction at the end portions of the inner cam shaft and the outer cam shaft.

  The two hydraulic actuators rotate the inner cam shaft and the outer cam shaft relative to each other by the supplied hydraulic pressure to control the operation angle of the intake valve, and rotate both the cam shafts relative to the crankshaft to each intake air. The valve opening and closing timing is controlled.

JP 2010-196486 A

  However, in the conventional variable valve operating device described in Patent Document 1, the two hydraulic actuators are integrally provided in series in the axial direction at each end of the both camshafts. The length in the axial direction of the device becomes longer and the device becomes larger.

  The present invention provides a variable valve operating apparatus that can control the relative rotational phase of an inner cam shaft and an outer cam shaft, and can control the relative rotational phase of both cam shafts with respect to a crankshaft, while reducing the size of the entire apparatus. It is intended to provide.

The invention according to claim 1 relates to a variable valve operating apparatus for an internal combustion engine capable of converting a relative rotational phase between an outer camshaft and an inner camshaft, and in particular, a rotor fixed to one of the two camshafts, A vane that divides the working chamber into an advance working chamber and a retard working chamber, and a storage chamber formed therein, and hydraulic pressure is selectively supplied to and discharged from the advance working chamber and the retard working chamber. As a result, the first rotating body that rotates relative to the driving rotating body toward the advance side or the retard angle side is fixed to either one of the camshafts and is rotatably accommodated in the accommodation chamber. A second rotating body provided to be rotatable relative to the driving rotating body and the first rotating body by a predetermined angle range; and an axial end surface of the second rotating body that slides on the driving rotating body. First lock provided on sliding surface And the second rotating body are provided so as to be movable along the rotation axis direction, and the relative rotation between the driving rotating body and the second rotating body is locked by engaging and advancing into the first lock recess, A first lock member that unlocks the drive rotator and the second rotator by retracting from the first lock recess;
A second lock recess provided at an end of the first lock member opposite to the first lock recess; and a second lock recess provided on the first rotating body so as to be movable along a rotation axis direction. Locking the relative rotation of the first rotating body and the second rotating body by engaging with advancement to the second position, and releasing the lock between the first rotating body and the second rotating body by retreating from the second lock recess. 2 locking members, a biasing member for biasing the second locking member in the direction of the second locking recess, and supplying hydraulic oil to engage the first locking member with the second locking recess. The second lock member is retreated against the urging force of the urging member together with the second lock member, and the second lock member is retreated from the first lock recess and by supplying hydraulic oil. Separated from the first locking member It is characterized by comprising that the second locking passage is moved in the direction to exit from the second locking recess, the.

  According to the present invention, it is possible to reduce the size of the entire apparatus while enabling the control of the relative rotation phases of the inner and outer cam shafts and the control of the relative rotation phases of the drive rotating body and the two cam shafts.

It is a longitudinal section showing a 1st embodiment of a variable valve apparatus concerning the present invention. 2 shows two drive cams provided for this embodiment, A shows the state of the same phase, and B shows the open angle state. It is a perspective view which decomposes | disassembles and shows the principal part of the variable valve apparatus of this embodiment. It is a longitudinal cross-sectional view which shows the action | operation of the hydraulic circuit of the variable valve apparatus of this embodiment. It is action | operation explanatory drawing which shows the state which converted the relative rotational phase of the 1st vane rotor and 2nd vane rotor in the same embodiment with respect to the sprocket to the most advanced angle side. It is action | operation explanatory drawing which shows the state which converted the relative rotational phase of the 1st vane rotor and the 2nd vane rotor in the same embodiment with respect to the sprocket to the most retarded angle side. It is action | operation explanatory drawing which shows the state by which the 2nd vane rotor was converted into the most retarded angle side in the state where the 1st vane rotor is the most advanced angle side. It is an expanded sectional view of the 1st lock mechanism and the 2nd lock mechanism which are provided to this embodiment. It is an expanded sectional view showing the state where the 1st lock pin used for this embodiment slipped out from the 1st lock hole. It is an expanded sectional view showing the state where the 2nd lock pin used for this embodiment came out of the 2nd lock hole, and the 1st lock pin engaged with another 1st lock hole. FIG. 5 is a developed cross-sectional view showing a state in which the engagement of the first lock pin and the second lock pin is released and the first lock pin is engaged with another first lock hole. The lift characteristics in which both exhaust valves in this embodiment are controlled to the same phase on the advance side are shown. The lift characteristics in which both exhaust valves in the present embodiment are converted to the same phase on the retard side together are shown. Only one of the exhaust valves in the present embodiment shows a lift characteristic in which the phase is converted to the advance side and an open angle state is obtained. It is action | operation explanatory drawing which shows the state which converted the relative rotation phase to the most advance angle side with respect to the sprocket about the 1st vane rotor and the 2nd vane rotor in 2nd Embodiment of this invention. It is action | operation explanatory drawing which shows the state which converted the relative rotational phase of the 1st vane rotor and the 2nd vane rotor in the same embodiment with respect to the sprocket to the most retarded angle side. It is action | operation explanatory drawing which shows the state which the 1st vane rotor converted into the most retarded angle side in the state where the 2nd vane rotor is the most advanced angle side. It is an expanded sectional view of the 1st lock mechanism and the 2nd lock mechanism which are provided to this embodiment. It is an expanded sectional view showing the state where the 1st lock pin used for this embodiment slipped out from the 1st lock hole. It is an expanded sectional view showing the state where the 2nd lock pin used for this embodiment came out of the 2nd lock hole, and the 1st lock pin engaged with the 1st lock hole. A state in which the first lock pin is engaged with the first lock hole and the second lock pin is disengaged from the second lock hole, and the first vane rotor is converted into the relative rotation position on the retard side. It is an expanded sectional view. The lift characteristics in which both exhaust valves in this embodiment are controlled to the same phase on the advance side are shown. The lift characteristics in which both exhaust valves in the present embodiment are converted to the same phase on the retard side together are shown. Only one of the exhaust valves in the present embodiment shows a lift characteristic in which the phase is converted to the advance side and an open angle state is obtained.

Embodiments of a variable valve operating apparatus for an internal combustion engine according to the present invention will be described below with reference to the drawings. In this embodiment, a gasoline specification, for example, applied to an exhaust valve side of a four-cylinder internal combustion engine is shown.
[First Embodiment]
The internal combustion engine has two exhaust valves per cylinder, and the variable valve operating device variably controls the open / close timing and operating angle (open angle) of both exhaust valves according to the engine operating state. .

  That is, as shown in FIGS. 1 to 5, the variable valve operating device is sprocket 1 that is rotationally driven via a timing chain by a crankshaft outside the engine, and is rotatable relative to the sprocket 1. A phase conversion mechanism 3 that is disposed between the provided camshaft 2 on the exhaust side, the sprocket 1 and the camshaft 2 to convert the relative rotational phases of the two and 1, and the phase conversion mechanism 3; And a hydraulic circuit 4 to be operated.

  In the two exhaust valves per cylinder, each umbrella portion opens and closes each open end on the cylinder side of two exhaust ports (not shown), and springs of the valve springs via valve lifters arranged at the respective upper ends. Forced in the closing direction by force.

  As shown in FIGS. 1 and 2, the camshaft 2 includes an inner hollow outer camshaft 5, and an inner solid inner camshaft 6 provided in the outer camshaft 5 so as to be relatively rotatable. The inner camshaft 6 is rotatably supported on the inner circumferential surface of the outer camshaft 5, while the outer camshaft 5 is rotatable on a cylinder head (not shown) via a cam bearing. It is supported.

  The outer camshaft 5 is integrally provided with a first drive cam 5a at a predetermined position on the outer peripheral surface by press-fitting to open the exhaust valve on one side of each cylinder via the valve lifter.

  The inner camshaft 6 is formed with a female screw hole 6c into which the male screw on the outer periphery of the shaft portion 9c of the cam bolt 9 is screwed in the inner axial direction of the tip portion 6b, and the outer camshaft 6 is located at a predetermined position in the axial direction. A second drive cam 6a is fixed that slides on the outer peripheral surface of the valve 5 and opens the exhaust valve on the one side through the same valve lifter.

  That is, the connecting shaft 7 is fixed through the through hole 6d formed in the diameter direction of the inner camshaft 6, and both end portions 7a and 7b of the connecting shaft 7 are press-fitted into the second drive cam 6a. By being fixed, the second drive cam 6 a is fixed to the inner camshaft 6. The connecting shaft 7 passes through a pair of insertion holes 5 c and 5 d that are formed through the outer cam shaft 5 in the diametrical direction, and both the insertion holes 5 c and 5 d are connected to the circumference of the outer cam shaft 5. It is formed in a slit shape along the direction, and the inner cam shaft 6 is allowed to rotate relative to the outer cam shaft 5 through the connecting shaft 7 within a predetermined angle range.

  The first drive cam 5a and the second drive cam 6a are disposed adjacent to each other with a slight gap therebetween as shown in FIGS. 1 and 2A, B, and the outer peripheral surfaces 5b, 6b are egg-shaped. The same cam profile is formed so that the one exhaust valve in one cylinder is opened and closed independently.

  As shown in FIGS. 1 and 3 to 5, the phase conversion mechanism 3 is disposed on one end side of the camshaft 2, and includes a housing 8 integrated with the sprocket 1 and one end of the outer camshaft 5. The first vane rotor 10 which is a first rotating body fixed in the axial direction by the cam bolt 9 and rotatably accommodated in the housing 8, and three protruding from the inner peripheral surface of the housing 8 Retarded oil chambers 12 which are three retarded working chambers separated by first to third shoes 11a to 11c and three first to third vanes 20 to 22 (to be described later) of the first vane rotor 10. And an advance oil chamber 13 which is an advance working chamber.

  The housing 8 is provided with a cylindrical housing body 14 that is open at both ends in the axial direction and also serves as the sprocket 1, and a front plate 15 and a rear plate 16 that close the axial front and rear openings of the housing body 14. A front plate 15 and a rear plate 16 are integrally coupled to the housing main body 14 by three bolts 17 from the axial direction.

  The housing body 14 is integrally formed of a sintered metal material and is integrally formed with a tooth portion 1a around which the chain is wound on the outer periphery of the front end. -3rd shoes 11a-11c are integrally projected inward.

  Each of the shoes 11a to 11c is formed in a substantially trapezoidal shape when viewed from the side, and is disposed at a position of approximately 180 ° in the circumferential direction of the housing main body 14 and one at a position therebetween. In the seal groove formed along the axial direction, a substantially U-shaped seal member 18 is fitted and fixed.

  Further, bolt insertion holes 11d through which the bolts 17 are inserted are formed through the radially outer peripheral sides of the shoes 11a to 11c.

  The first shoe 11a is formed with a flat first convex surface 11e on one side surface in the circumferential direction, while the second shoe 11b is also flat on one side surface facing the one side surface of the first shoe 11a in the circumferential direction. The second convex surface 11f is formed, and the convex surfaces 11e and 1f face each other when a first vane 20 described later rotates counterclockwise or clockwise as shown in FIGS. The side surfaces are in contact with each other to restrict the first vane rotor 10 to the most retarded angle and advanced angle positions.

  The front plate 15 is formed by forming a metal plate into a relatively thin disk shape by press molding, and a large-diameter hole 15a in which a flange-like seat portion 9c of the head 9a of the cam bolt 9 is accommodated and disposed at the center. Are formed, and three bolt insertion holes 15b through which the bolts 17 are inserted are formed in the circumferentially equidistant positions on the outer peripheral side. Further, the front plate 15 is formed with two small-diameter breathing holes 15c and 15d penetratingly formed on the inner peripheral portion. The breathing holes 15c and 15d allow the first vane rotor 10 to communicate with the second sliding hole 42 of the second locking mechanism 41, which will be described later, at the relative rotational position of the most advanced angle and the most retarded angle, so that the outside air communicates. This ensures good slidability.

  The rear plate 16 is formed of a sintered alloy so as to be thicker than the front plate 15, and a cylindrical rear end portion of the rotor 19 of the first vane rotor 10 described later is inserted in the center to rotate. A support hole 16a that is freely supported is formed through. Further, three female screw holes 16b into which the male screws at the tip portions of the respective bolts 17 are screwed are formed at circumferentially equidistant positions on the outer peripheral side.

  The rear plate 16 is formed with two first and second lock recesses 31a and 31b of the first lock mechanism 28, which will be described later, at predetermined positions on the outer periphery. As will be described later, the lock holes 31a and 31b engage with the first lock pin 30 that is the first lock member of the first lock mechanism 28 at the relative rotational position of the most advanced angle and the most retarded angle of the first vane rotor 10. Thus, they are formed with a predetermined interval on the same circular arc locus.

  In addition, a positioning pin 16c that engages with a positioning hole 14a formed in the second shoe 11b of the housing main body 14 and positions the housing main body 14 protrudes at a predetermined position on the outer peripheral portion of the rear plate 16. ing.

  The first vane rotor 10 is integrally formed of, for example, a sintered metal. As shown in FIGS. 1, 3, and 5, the first vane rotor 10 radiates from the center-side first rotor 19 and the outer periphery of the first rotor 19. The first to third vanes 20 to 22 project in the direction.

  The first rotor 19 is formed in a substantially cylindrical shape as a whole, and is formed in a stepped diameter shape having a large and small outer diameter, and a large diameter portion 19a between the first vane 20 and the second vane 21 is formed. On the other hand, a space between the first vane 20 and the third vane 22 is formed in the small diameter portion 19b.

  This first rotor 19 has an insertion hole 19d through which the shaft portion 9c of the cam bolt 9 is inserted in the center of a disk wall 19c formed at the front end portion along the axial direction. First and second fitting holes 19e and 19f having stepped diameters are formed through which the respective end portions 5d and 6c of the outer cam shaft 5 and the inner cam shaft 6 are inserted and fitted. The first rotor 19 is fastened and fixed from the axial direction to the tip portion 6c of the inner camshaft 6 by the cam bolt 9 via the disk wall 19c.

  The first rotor 19 has a distal end portion 5d of the outer camshaft 5 fitted in the first fitting hole 19e, but is not coupled to the outer camshaft 5 and ensures free relative rotation. Has been.

  Further, an accommodation chamber 26 for accommodating the second vane rotor 23 is formed in the rear end side inside the first fitting hole 19e into which the outer camshaft 5 of the first rotor 19 is fitted. As shown in FIG. 5, the housing chamber 26 is formed in a circular rotor housing portion 26a formed in the center of the first rotor 19, and in a fan frame shape inside the large diameter portion 19a. It is comprised from the fan-shaped vane accommodating part 26b connected with the accommodating part 26a.

  In the large-diameter portion 19a, a second sliding hole 42 through which a second lock pin 43, which is a second lock member of the second lock mechanism 41, slides in the substantially central position in the circumferential direction. Has been.

  As shown in FIG. 5, the first to third vanes 20 to 22 are set to have substantially the same width and thickness in the circumferential direction. Sealing members 27 that are in sliding contact with the inner peripheral surface of the main body 14 and seal the oil chambers 12 and 13 are fitted and fixed, respectively.

  When the first vane 20 rotates relative to the advance and retard sides, one side surface of the first vane 20 contacts the first convex surface 11e in the counterclockwise direction (advance oil chamber 13 side). The other side surface of the clockwise direction side (retarding oil chamber 12 side) is in contact with the second convex surface 11f so that the maximum relative rotation of each is regulated.

  As shown in FIGS. 1, 3, and 5, the second vane rotor 23 housed in the housing chamber 26 is an annular first member that is rotatably housed and held in the rotor housing portion 26 a of the first rotor 19. The two rotors 24 and one fourth vane 25 that protrudes integrally on the outer peripheral surface of the second rotor 24 and is rotatably accommodated in the vane accommodating chamber 26b.

  The second rotor 24 has an outer diameter slightly smaller than the inner diameter of the rotor accommodating portion 26a, and a cylindrical minute clearance is formed between the outer peripheral surface and the inner peripheral surface of the rotor accommodating portion 26a. Free rotation is ensured, and the axial length thereof is formed substantially the same as the axial length of the rotor accommodating portion 26a.

  In the second rotor 24, as shown in FIG. 1, the distal end portion 5d of the outer cam shaft 5 is press-fitted and fixed in an annular fixing hole 24a formed penetrating in the central internal axis direction.

  The fourth vane 25 is formed in a fan shape corresponding to the vane accommodating portion 26b, and is accommodated in the vane accommodating portion 26b so as to be relatively rotatable. A clearance is formed between the outer peripheral surface 25b and the inner peripheral surface of the vane housing portion 26b.

  Further, a first sliding hole 29 through which the first lock pin 30 of the first lock mechanism 28 slides penetrates the counterclockwise direction of the fourth vane 25 in the counterclockwise direction, that is, the internal axis direction of the retarded angle side. Is formed.

  The hydraulic circuit 4 selectively supplies or discharges hydraulic pressure to or from each retard oil chamber 12 and each advance oil chamber 13, and as shown in FIGS. 12 is a retarded-side passage 36 that communicates with each other, an advance-side passage 37 that communicates with each of the advance oil chambers 13, and oil that selectively supplies hydraulic pressure to each of the passages 36 and 37 via an electromagnetic switching valve 38. A pump 39 and a drain passage 40 that selectively communicates with the passages 36 and 37 via an electromagnetic switching valve 38 are provided.

  As shown in FIG. 4, the retard angle side passage 36 communicates with the groove groove 36 a formed on the outer peripheral surface of the outer camshaft 5 and the groove groove 36 a, and continuously into the inner camshaft 6. The formed radial hole and axial hole 36b, the radial hole 36c formed on the tip side of the axial hole 36a, and the inner peripheral surface of the second fitting hole 19f of the first rotor 19 are formed. An annular groove 36d communicating with the radial hole 36c and three retardations formed in the inner radial direction of the first rotor 19 and communicating the annular groove 36d and each retardation oil chamber 12 Oil holes 36e.

  As shown in FIG. 4, the advance side passage 37 is connected to the groove groove 37 a formed on the outer peripheral surface of the outer camshaft 5, and to the groove groove 37 a, and continuously into the inner camshaft 6. The formed radial hole and axial hole 37b, the radial hole 37c formed on the distal end side of the axial hole 37a, and the distal end portion of the outer camshaft 5 are formed in the radial direction, and the diameter A communication hole 37d communicating with the direction hole 37c, an annular groove 37e formed on the inner peripheral surface of the first fitting hole 19e of the first rotor 19 and communicating with the communication hole 37d, and the first rotor 19 It has three advance oil holes 37f that are formed in the inner radial direction and communicate with the annular groove 37e and each advance oil chamber 13.

  The electromagnetic switching valve 38 is a four-port two-position valve, and an internal spool valve is moved in the axial direction by the output and cutoff of a control current from a control unit (ECU) (not shown) to the electromagnetic coil. 36 and 37 are selectively switched between a discharge passage 39a and a drain passage 40 of the oil pump 39. That is, when energized from the control unit, the discharge passage 39a and the retard side passage 36 are communicated with each other, and at the same time, the drain passage 40 and the advance side passage 37 are communicated. In addition, the drain passage 40 and the retard side passage 36 are communicated with each other.

  In the control unit, an internal computer inputs information signals from various sensors such as a crank angle sensor, an air flow meter, a water temperature sensor, a throttle valve opening sensor, etc., not shown, and detects the current engine operating state. A control current is output to the electromagnetic coil of the electromagnetic switching valve 38 in accordance with the engine operating state.

  As shown in FIGS. 1, 3, and 8, the first lock mechanism 28 slides into the sliding hole 29 formed in the second vane 25 of the second vane rotor 23, and slides into the sliding hole 29. A first lock pin 30 that is freely housed and is provided so as to be capable of moving forward and backward with respect to the rear plate 16 side, and a front end portion 30a of the first lock pin 30 that engages with the first lock pin 30 is formed on the rear plate 16. The two first lock holes 31a and 31b for locking the two-vane rotor 23 and the distal end portion 30a of the first lock pin 30 are engaged with or released from the lock holes 31a and 31b according to the engine operating state. And a first engagement / disengagement mechanism.

  The first sliding hole 29 is formed in a substantially uniform diameter with a relatively large inner diameter, and is formed to penetrate in the axial direction.

  The first lock pin 30 has a rear end portion corresponding to the first sliding hole 29 and an outer peripheral surface having a substantially uniform outer diameter, and a front end portion 30a is formed from the inner diameter of the first lock holes 31a and 31b. A stepped pressure receiving surface 30b is formed between the rear end portion and the tip end portion 30a while being formed in a slightly small step with a small diameter. An annular first pressure receiving chamber 32 is formed between the first oil groove 25a formed in a notch at the tip hole edge of the first sliding hole 29 and the pressure receiving surface 30b.

  The first lock holes 31a and 31b are each formed in a cylindrical shape with a bottom, and are formed at a predetermined interval in the circumferential direction of the inner peripheral surface of the rear plate 16, and the one lock hole 31a is the second vane rotor 23. Is formed at a position where the first lock pin 30 is engaged from the axial direction when the second vane rotor 23 is relatively rotated to the maximum retarded angle side. Further, the first lock pin 30 is formed at a position where the first lock pin 30 is engaged from the axial direction.

  Therefore, when the first lock pin 30 is engaged with the first lock hole 31a on one side, the relative rotation angle between the housing 8 and the second vane rotor 23 is the maximum advance angle conversion angle (phase) optimum for engine start. When the first lock pin 30 is engaged with the first lock hole 31b on the other side, the relative rotation angle between the housing 8 and the second vane rotor 23 becomes the maximum retarded conversion angle (phase). Is set to

  Since the outer diameter of the first lock pin 30 is set to be larger than the inner diameter of the second sliding hole 42 described later, the rear end outer peripheral edge 30b is used for the second sliding when retreating. The maximum backward movement is restricted by contacting the edge of the hole 42. At this point, the tip 30a is completely removed from the first lock holes 31a and 31b.

  The first engagement / disengagement mechanism also serves as a part of the engagement / disengagement mechanism of the second lock mechanism 41, and is elastic between a rear end portion of a second lock pin 43 described later and an inner end surface of the front plate 15. And a coil spring 33 that biases the first lock pin 30 in the advancing direction (the first lock holes 31a and 31b) via the second lock pin 43 and the first pressure receiving chamber 32 through the first pressure receiving chamber 32. A hydraulic pressure is supplied to the pressure receiving surface 30b and the first lock holes 31a and 31b, and a first release hydraulic circuit 34 that releases the lock by retracting the first lock pin 30 from the first lock holes 31a and 31b. Yes.

  As shown in FIGS. 1, 4 and 8, the first release hydraulic circuit 34 is configured independently of the hydraulic circuit 4 and communicates with the first lock holes 31a and 31b. And a first electromagnetic switching valve 46 that selectively connects the discharge passage 39a of the oil pump 39 and the drain passage 40 to the release passage 35.

  One end side of the first release passage 35 is appropriately connected to the oil pump 39 and the drain passage 40 via the first electromagnetic switching valve 46. The other end side is formed in the groove groove 35a and the radial hole formed on the outer peripheral surface of the outer camshaft 5 and the inner axial direction of the inner camshaft 6, and the axial hole 35b communicated with the radial hole. Further, the outer camshaft 5 is formed by a communication hole 35c that is formed so as to penetrate in the radial direction on the distal end side and communicates with the axial hole 35b and the first pressure receiving chamber 32 (first lock holes 31a, 31b). Yes.

  The first electromagnetic switching valve 46 is controlled by an on / off control signal from the control unit that controls the electromagnetic switching valve 38, and the discharge passage 39 a and the drain passage 40 are connected to the first release passage 35. Is appropriately controlled to be switched.

  As shown in FIGS. 1, 4, and 8, the second lock mechanism 41 includes a second sliding hole 42 formed in the inner axial direction of the first rotor 19 of the first vane rotor 10, and the second A second lock pin 43 that is slidably received in the sliding hole 42 and is provided to be movable forward and backward with respect to the first lock pin 30; and a rear end portion of the first lock pin 30; A second lock hole 44 for connecting the first vane rotor 10 and the second vane rotor 23 by engaging the front end 43a of the second lock pin 43, and the front end 43a of the second lock pin 43 according to the engine operating state. A second engagement / disengagement mechanism that engages with or releases the engagement with the second lock hole 41.

  The second sliding hole 42 is arranged in series with the first sliding hole 29 at a predetermined relative rotational position of the first vane rotor 10 and the second vane rotor 23 and has an inner diameter slightly smaller than that of the first sliding hole 29. Are formed to have a small uniform diameter and are formed to penetrate in the axial direction.

  The second lock pin 43 has a rear end portion corresponding to the second sliding hole 42 and an outer peripheral surface formed with a substantially uniform outer diameter, and the outer diameter is set smaller than that of the first lock pin 30. In addition, the distal end portion 43 a is formed in a small diameter slightly smaller than the inner diameter of the second lock hole 44. A step-shaped second pressure receiving surface 43b is formed between the rear end portion of the second lock pin 43 and the front end portion 43a. As described above, the first lock pin 30, the second lock pin 43, the first lock holes 31a and 31b, and the second lock hole 44 are arranged in series in the axial direction, and their projected areas overlap each other. It is in a state.

  Further, a second oil groove 45 is formed in the rear edge hole edge of the first sliding hole 29, and a second pressure receiving chamber is provided between the second oil groove 45 and the second pressure receiving surface 43b. 50 is formed. The second oil groove 45 communicates with a second release passage 48 described later.

  The second lock hole 44 is formed in a bottomed cylindrical shape, and when the tip end portion 43a of the second lock pin 43 is engaged (locked), the first lock pin 30 and the second lock pin 43 are The first vane rotor 10 and the second vane rotor 23 are coupled in series.

  As described above, the second engagement / disengagement mechanism is elastically mounted between the rear end portion of the second lock pin 43 and the inner end surface of the front plate 15 to move the second lock pin 43 in the advancing direction (second direction). Oil pressure is supplied to the second pressure receiving surface 43b and the second lock hole 44 via the second pressure receiving chamber 50 and the coil spring 33, which is an elastic member that urges the second lock pin 43 in the direction of the lock hole 44). The second release hydraulic circuit 47 is configured to release the lock by retreating from the second lock hole 44.

  As shown in FIGS. 1, 4, and 8, the second release hydraulic circuit 47 is configured independently of the hydraulic circuit 4 and the first release hydraulic circuit 34, and includes the second oil groove 45. A second release passage 48 that is a second lock passage communicating with the second pressure receiving chamber 50 through the second release passage 48, and the discharge passage 39a of the oil pump 39 and the drain passage 40 are selectively communicated with the second release passage 48. And a second electromagnetic switching valve 49 to be operated.

  One end side of the second release passage 48 is appropriately connected to the oil pump 39 and the drain passage 40 via the second electromagnetic switching valve 49, and the other end side is formed on the outer peripheral surface of the outer camshaft 5. The groove groove 48a and the radial hole formed in the inner axial direction of the inner camshaft 6, the axial hole 48b communicating with the radial hole, and further penetrating in the radial direction to the distal end side of the outer camshaft 5 The communication hole 48c is formed to communicate with the axial hole 48b and the second pressure receiving chamber 50 (second lock hole 44).

The second electromagnetic switching valve 49 is controlled by an on / off control signal from the control unit to appropriately switch the discharge passage 39a and the drain passage 40 with respect to the second release passage 48. ing.
[Operation of this embodiment]
First, when the engine is started, as shown in FIGS. 5 and 8, the distal end portion 30a of the first lock pin 30 is previously engaged in the first lock hole 31a on the advance side by the spring force of the coil spring 33. In addition, the tip end portion 43 a of the second lock pin 43 is also engaged in the second lock hole 44. Thereby, the first lock pin 30 and the second lock pin 43 are coupled in series. For this reason, the first vane rotor 10 and the second vane rotor 23 are locked to the relative rotation position on the advance side which is optimal for starting with respect to the sprocket 1.

  Therefore, as shown in FIG. 2A, the two drive cams 5a and 6a have the same rotational phase via the outer cam shaft 5 and the inner cam shaft 6, and the opening / closing timing characteristics of one exhaust valve are as shown in FIG. As shown by the thick solid line, the phase is maintained at the initial advance side.

  Therefore, when the engine is started by turning on the ignition switch from this state, good startability can be obtained by smooth cranking.

  In a predetermined operating range after the engine is started, a control current is output from the control unit to the electromagnetic switching valve 38 and the first electromagnetic switching valve 46, and first, the discharge passage 39a and the first release passage 35 are communicated. Therefore, the hydraulic oil discharged from the oil pump 39 is supplied to the first pressure receiving chamber 32 through the first release passage 35 and becomes high pressure. As a result, the first lock pin 30 retreats against the spring force of the coil spring 33 together with the second lock pin 43 by the high hydraulic pressure acting on the first pressure receiving surface 30b, and the first lock hole on one side is moved. The lock between the rear plate 16 (housing 8) and the second vane rotor 23 is released from 31a. Here, since the second vane rotor 23 and the first vane rotor 10 are still in a coupled state (locked state), both the 10 and 23 are unlocked together with the housing 8 to ensure free relative rotation. Will be.

  At the same time, the discharge passage 39a and the retard side passage 36 are communicated, and the retard side passage 37 and the drain passage 40 are communicated. For this reason, the hydraulic pressure discharged from the oil pump 39 is supplied to each retarded oil chamber 12 through the retarded-side passage 36 and the like, and each retarded oil chamber 12 becomes high pressure, The hydraulic pressure in the advance oil chamber 13 is discharged to the oil pan, and the inside becomes a low pressure.

  Therefore, as shown in FIG. 6, the first vane rotor 10 and the second vane rotor 23 rotate relative to the housing 8 toward the retard side as the retard oil chambers 13 increase in pressure. As a result, the outer cam shaft 5 and the inner cam shaft 6 are synchronously rotated together counterclockwise and the first drive cam 5a and the second drive cam 6a are in the same rotational phase, The opening / closing timings of the two exhaust valves are controlled to the retard side, and the opening / closing timing characteristics are converted into the most retarded phase as shown by the thick solid line in FIG.

  At this time, the second electromagnetic switching valve 49 is in a state where the second release passage 48 and the drain passage 40 are communicated with each other without outputting a control current from the control unit. For this reason, as shown in FIG. 9, the first vane rotor 10 is maintained in the locked state with the second vane rotor 23 because the second lock pin 43 is maintained in the engaged state with the second lock hole 44. doing.

  When the engine operating state further changes, the control current from the control unit to the electromagnetic switching valve 38 and the first electromagnetic switching valve 46 is cut off, and the control current is output to the second electromagnetic switching valve 49. Therefore, the drain passage 40 and the first release passage 35 communicate with each other, and the first pressure receiving chamber 32 (the other first lock hole 31b) becomes low pressure, while the discharge passage 39a and the second release passage 48 communicate with each other. The hydraulic oil discharged from the pump 39 is supplied to the second pressure receiving chamber 50 (second lock hole 44) through the second release passage 48 and becomes high pressure.

  Therefore, as the pressure of the second lock hole 44 is increased, the first lock pin 30 moves forward and engages with the other first lock hole 31b as shown in FIG. Moves backward against the spring force of the coil spring 33 and comes out of the second lock hole 44, and the lock (coupling) between the first vane rotor 10 and the second vane rotor 23 is released. As a result, the second vane rotor 23 is locked to the rear plate 16 (housing 8) and held at the relative rotation position on the retard side, but the first vane rotor 10 is allowed to freely rotate.

  At this time, the discharge passage 39a and the advance side passage 37 are in communication with each other, and the retard side passage 36 and the drain passage 40 are in communication, so that the discharge of the oil pump 39 is performed on each advance oil chamber 13 side. While the hydraulic pressure is supplied to increase the pressure, the internal hydraulic oil is discharged into the oil pan through the drain passage 40 and becomes a low pressure state at each retarded oil chamber 12 side.

  Therefore, as shown in FIGS. 7 and 11, only the first vane rotor 10 rotates relative to the housing 8 relative to the advance side, and the second vane rotor 23 is restricted from relative rotation toward the advance side. The relative rotation position on the most retarded angle side is held.

  As a result, the first drive cam 5a on the outer camshaft 5 side is held at the rotational position on the retard side, but the second drive cam 6a on the inner camshaft 6 side is The opening / closing timing of the two exhaust valves is controlled to the rotational position on the advance side as in the start, and the first drive cam 6a is opened (open angle state).

  Therefore, as shown in FIG. 14, the opening / closing timing characteristics of one exhaust valve are pushed by the two drive cams 5a and 6a for a time longer than the time during which the valve lifter is pushed during the initial phase. That is, the time during which one exhaust valve is open becomes longer, and the scavenging time of the combustion gas continuously increases.

  In addition, according to various changes in the engine operating state and when the engine is stopped, the control unit performs energization control to the electromagnetic switching valve 38 and the first and second electromagnetic switching valves 36 and 49, thereby providing the first. The relative rotational positions of the vane rotor 10 and the second vane rotor 23 can be arbitrarily changed.

  Thus, the outer cam shaft 5 and the inner cam shaft 6 can be arbitrarily rotated relative to each other, and the first drive cam 5a and the second drive cam 6a are converted into the same phase toward the advance side and the retard side. Moreover, the opening angle control by the phase shift can be arbitrarily performed.

  As described above, in this embodiment, the relative rotation phases of the outer camshaft 5 and the inner camshaft 6 are controlled separately or synchronously using the hydraulic circuits 4, 34, 47, and the housing 8 Since the relative rotational phase of the camshafts 5 and 6 with respect to the (crankshaft) can be converted, the opening / closing timing control of the exhaust valve can be performed with high accuracy.

  In addition, since the second vane rotor 23 is accommodated in the first rotor 19 of the first vane rotor 10 and the two vane rotors 10 and 23 are arranged in parallel, the apparatus is compared with the prior art arranged in series. It is possible to sufficiently shorten the axial length. As a result, the mountability to the engine is improved.

  Further, since the first rotor 19 of the first vane rotor 10 is not made large in diameter as a whole, but is constituted by the large diameter portion 19a and the small diameter portion 19b, the retard oil chamber 12 is formed by the small diameter portion 19b. Since the volume reduction of the advance oil chamber 13 can be suppressed and the pressure receiving area of each of the vanes 20 to 22 can be increased, the retardation of the first vane rotor 10 due to the hydraulic oil supplied to the oil chambers 12 and 13 can be achieved. Thus, it is possible to ensure quick response of relative rotation toward the advance side.

  In the present embodiment, the first lock pin 30 and the second lock pin 43 are arranged in series, and a second lock hole 44 is formed at the rear end portion of the first lock pin 30, and this second lock Since the first vane rotor 10 and the second vane rotor 23 are locked or released by supplying and discharging the hydraulic pressure to the hole 44, the entire structure can be simplified and the space can be effectively used.

That is, when the first and second lock holes 31 and 44 are formed in different members such as the rear plate 16 and the front plate 15 and the lock pins 30 and 43 are moved forward and backward in the opposite directions, Although the overall structure is complicated and the handling of the hydraulic circuit is also complicated, in the present embodiment, the second lock hole 44 is formed using the first lock pin 30, and therefore the overall structure is simplified. At the same time, the space can be used effectively. As a result, the manufacturing work and the assembling work are facilitated, and the manufacturing cost and the assembling work cost can be reduced.
[Second Embodiment]
15 to 21 show a second embodiment of the present invention, which is also applied to an exhaust valve on one side of two exhaust valves per cylinder, and the basic structure is substantially the same as that of the first embodiment. In the following description, common components are denoted by the same reference numerals. In the configuration different from the first embodiment, the other first lock hole 31b is abolished and the arrangement of the second vane rotor 23 with respect to the first vane rotor 10 is reversed, but the initial relative rotational phase of both the vane rotors 10 and 23 is The same.

  That is, when the engine is started, as shown in FIGS. 15 and 18, the tip portion 30 a of the first lock pin 30 is engaged in advance in the first lock hole 31 a on the advance side by the spring force of the coil spring 33. In addition, the tip end portion 43 a of the second lock pin 43 is also engaged in the second lock hole 44. Thereby, the first lock pin 30 and the second lock pin 43 are coupled in series. For this reason, the first vane rotor 10 and the second vane rotor 23 are locked to the relative rotation position on the advance side which is optimal for starting with respect to the sprocket 1.

  Therefore, as shown in FIG. 2A, the two drive cams 5a and 6a have the same rotational phase via the outer cam shaft 5 and the inner cam shaft 6, and the opening / closing timing characteristics of one exhaust valve are as shown in FIG. As shown by the thick solid line, the phase is maintained at the initial advance side.

  Therefore, when the engine is started by turning on the ignition switch from this state, good startability can be obtained by smooth cranking.

  In a predetermined operating range after the engine is started, a control current is output from the control unit to the electromagnetic switching valve 38 and the first electromagnetic switching valve 46, and the discharge passage 39a and the first release passage 35 are communicated. The hydraulic oil discharged from the oil pump 39 is supplied to the first pressure receiving chamber 32 through the first release passage 35 and becomes high pressure. As a result, the first lock pin 30 retreats against the spring force of the coil spring 33 together with the second lock pin 43 by the high hydraulic pressure acting on the first pressure receiving surface 30b, and the first lock hole on one side is moved. The lock between the rear plate 16 (housing 8) and the second vane rotor 23 is released from 31a. Here, since the second vane rotor 23 and the first vane rotor 10 are still in a coupled state (locked state), both the 10 and 23 are unlocked together with the housing 8 to ensure free relative rotation. Will be.

  At the same time, the electromagnetic switching valve 38 connects the discharge passage 39a and the retard side passage 36, and also connects the advance side passage 37 and the drain passage 40. For this reason, the hydraulic pressure discharged from the oil pump 39 is supplied to each retarded oil chamber 12 through the retarded-side passage 36 and the like, and each retarded oil chamber 12 becomes high pressure, The hydraulic pressure in the advance oil chamber 13 is discharged to the oil pan, and the inside becomes a low pressure.

  Therefore, as shown in FIG. 16, the first vane rotor 10 and the second vane rotor 23 rotate relative to the housing 8 toward the retard side as the retard oil chambers 13 increase in pressure. As a result, the outer cam shaft 5 and the inner cam shaft 6 are synchronously rotated together counterclockwise and the first drive cam 5a and the second drive cam 6a are in the same rotational phase, The opening / closing timings of the two exhaust valves are controlled to the retard side, and the opening / closing timing characteristics are converted into the most retarded phase as shown by the thick solid line in FIG.

  At this time, the second electromagnetic switching valve 49 is in a state where the second release passage 48 and the drain passage 40 are communicated with each other without outputting a control current from the control unit. For this reason, as shown in FIG. 19, the first vane rotor 10 is maintained in the locked state with the second vane rotor 23 because the second lock pin 43 is maintained in the engaged state with the second lock hole 44. doing.

When the engine operating state further changes, the control current from the control unit to the first electromagnetic switching valve 46 is cut off, and the control current is output to the electromagnetic switching valve 38 and the second electromagnetic switching valve 49.
Therefore, the drain passage 40 and the first release passage 35 communicate with each other, and the first pressure receiving chamber 32 (first lock hole 31a) becomes a low pressure, while the discharge passage 39a and the second release passage 48 communicate with each other with the oil pump 39. The hydraulic fluid discharged from the gas passes through the second release passage 48 and is supplied to the second pressure receiving chamber 50 (second lock hole 44) to become a high pressure.

  Accordingly, as the pressure of the second lock hole 44 is increased, the first lock pin 30 moves forward and engages with the first lock hole 31a as shown in FIG. It moves backward against the spring force of the spring 33 and comes out of the second lock hole 44, and the lock (coupling) between the first vane rotor 10 and the second vane rotor 23 is released. As a result, the second vane rotor 23 is locked to the rear plate 16 (housing 8) and held at the relative rotation position on the advance side, but the first vane rotor 10 is allowed to freely rotate.

  At this time, the discharge passage 39a and the retard side passage 36 are in communication with each other, and the advance side passage 37 and the drain passage 40 are in communication with each other. While the discharge hydraulic pressure of the oil pump 39 is supplied and becomes high pressure, the hydraulic oil inside is discharged into the oil pan through the drain passage 40 and the low pressure state is maintained on each advance oil chamber 13 side. .

  Accordingly, as shown in FIGS. 17 and 21, only the first vane rotor 10 rotates relative to the housing 8 relative to the retard side, and the second vane rotor 23 is restricted from rotating relative to the retard side. It is held at the relative rotation position on the most advanced angle side.

  As a result, the second drive cam 6a on the inner camshaft 6 side is held at the rotational position on the advance side, but the first drive cam 5a on the outer camshaft 5 side has an opening / closing timing of one exhaust valve. It is controlled to the rotational position on the retarded angle side to be in an open state with respect to the first drive cam 6a (open angle state).

  Therefore, as shown in FIG. 24, the opening / closing timing characteristic of one exhaust valve is pushed by the two drive cams 5a and 6a for a time longer than the time during which the valve lifter is pushed at the initial phase. That is, the time during which one exhaust valve is open becomes longer, and the scavenging time of the combustion gas continuously increases.

  In addition, according to various changes in the engine operating state and when the engine is stopped, the control unit performs energization control to the electromagnetic switching valve 38 and the first and second electromagnetic switching valves 46 and 49, thereby providing the first. The relative rotational positions of the vane rotor 10 and the second vane rotor 23 can be arbitrarily changed. Thus, the outer cam shaft 5 and the inner cam shaft 6 can be arbitrarily rotated relative to each other, and the first drive cam 5a and the second drive cam 6a are converted into the same phase toward the advance side and the retard side. Moreover, the opening angle control by the phase shift can be arbitrarily performed.

  As described above, in the present embodiment, as in the first embodiment, the relative rotational phases of the outer cam shaft 5 and the inner cam shaft 6 are separately or synchronized using the hydraulic circuits 4, 34, 47. Therefore, the relative rotation phase of the camshafts 5 and 6 with respect to the housing 8 (crankshaft) can be converted, so that the opening / closing timing control of the exhaust valve can be performed with high accuracy.

  In addition, since the second vane rotor 23 is accommodated in the first rotor 19 of the first vane rotor 10 and the two vane rotors 10 and 23 are arranged in parallel, the apparatus is compared with the prior art arranged in series. It is possible to sufficiently shorten the axial length. As a result, the mountability to the engine is improved.

  Other functions and effects are the same as those of the first embodiment.

  The present invention is not limited to the configuration and control action of each of the above embodiments, and the first vane rotor 10 and the second vane rotor 23 are arbitrarily locked or unlocked together and separately according to the engine operating state. Control can be performed.

  In each of the above embodiments, two drive cams 5a and 6a are used for one exhaust valve. However, for each of the two exhaust valves per cylinder, the drive cam 5a and the drive cam 6a are used separately. It is also possible to control the opening angle state while opening and closing. In addition to the exhaust valve, the present invention can also be applied to an intake valve.

  Further, in the present invention, the first rotating body and the second rotating body are not limited to the vane rotor, and for example, a plurality of gear gears or the like can be used instead of the vane rotor.

  Furthermore, unlocking of the first rotating body relative to the driving rotating body, unlocking of the first rotating body and the second rotating body, and the like can be performed by an electrical means other than hydraulic pressure such as an electric motor.

The technical ideas of the invention other than the claims ascertained from the embodiment will be described below.
[Claim a] A variable valve operating apparatus for an internal combustion engine according to claim 1,
The first rotating body is at the most advanced angle or the most retarded relative rotation position with respect to the drive rotating body, and the second rotating body is at the opposite relative rotation position with respect to the first rotating body. In this case, at least one of the first lock recesses and the first lock member are engaged and locked.
[Claim b] A variable valve operating apparatus for an internal combustion engine according to claim a,
At least while the drive rotator is rotating, the second rotator is always subjected to a rotational torque in the retard direction with respect to the first rotator,
At the position where the first rotating body is at the most advanced relative rotation position with respect to the drive rotating body, and at the position where the second rotating body is at the most retarded relative rotation with respect to the first rotating body, The variable valve operating apparatus for an internal combustion engine, wherein at least one of the first lock recesses and the first lock member are locked.
[Claim c] A variable valve operating apparatus for an internal combustion engine according to claim b,
When the first rotating body is at the most advanced relative rotational position with respect to the drive rotating body, and the second rotating body is at the most advanced relative rotating position with respect to the first rotating body. The variable valve operating apparatus for an internal combustion engine, wherein the first lock member locks the relative rotation of the drive rotary body and the second rotary body by advancing and engaging inside another first lock recess. .
[Claim d] A variable valve operating apparatus for an internal combustion engine according to claim c,
The internal combustion engine characterized in that the second lock recess and the second lock member are engaged and locked with respect to the first rotary body at a position where the second rotary body has a relative rotation at a most advanced angle. Variable valve gear for engine.
[Claim e] A variable valve operating apparatus for an internal combustion engine according to claim b,
The variable movement of the internal combustion engine, wherein the second lock recess and the second lock member are engaged and locked with respect to the first rotary body at a relative rotational position of the most retarded angle of the second rotary body. Valve device.
[Claim f] A variable valve operating apparatus for an internal combustion engine according to claim 1,
The variable valve operating apparatus for an internal combustion engine, wherein the storage chamber is provided so as to open on one side surface in the axial direction of the first rotating body.
[Claim g] A variable valve operating apparatus for an internal combustion engine according to claim f,
A part of the rotor in the first rotating body is formed with a larger diameter than the other part, and a part of the storage chamber is formed in the large diameter part. Variable valve gear.
(Claim h) A variable valve operating apparatus for an internal combustion engine according to claim 1,
The variable valve operating apparatus for an internal combustion engine, wherein the first lock member is restricted from moving into the first rotating body.
(Claim i) A variable valve operating apparatus for an internal combustion engine according to claim h,
The variable valve operating apparatus for an internal combustion engine, wherein the first lock member is formed larger than an inner diameter of a second sliding hole in which the second lock member slides in the first rotating body.
[Claim j] A variable valve operating apparatus for an internal combustion engine according to claim i,
The first lock member and the second lock member are constituted by a lock pin formed in a cylindrical shape,
The variable valve operating apparatus for an internal combustion engine, wherein an outer diameter of the first lock member is formed larger than an outer diameter of the second lock member.
[Claim k] A variable valve operating apparatus for an internal combustion engine according to claim j,
The variable valve operating apparatus for an internal combustion engine, wherein the first lock member and the second lock member are formed with a small diameter portion on a side engaged with the first lock recess and the second lock recess.
[Claim 1] A variable valve operating apparatus for an internal combustion engine according to claim 1,
While the first lock member is engaged in the first lock recess, and the second lock member is not engaged in the second lock recess, the first rotating body is against the drive rotating body. A variable valve operating apparatus for an internal combustion engine, characterized by having a state of relative rotation.
[Claim m] A variable valve operating apparatus for an internal combustion engine according to claim 1, wherein:
The first rotary member rotates relative to the drive rotary body in a state where the first lock member is retracted from the first lock concave portion and the second lock member is engaged in the second lock concave portion. A variable valve operating apparatus for an internal combustion engine, characterized in that:
[Claim n] A variable valve operating apparatus for an internal combustion engine according to claim 1,
A state in which the first rotating member rotates relative to the driving rotating body in a state where the first locking member is engaged in the first locking recess and the second locking member is retracted from the second locking recess. A variable valve operating apparatus for an internal combustion engine, comprising:
[Claim o] A variable valve operating apparatus for an internal combustion engine according to claim 1,
The first lock recess is formed on an inner end surface of a rear plate located on each drive cam side of the outer cam shaft and the inner cam shaft in the axial direction of the drive rotating body. Variable valve device.
[Claim p] A variable valve operating apparatus for an internal combustion engine according to claim 1,
An internal combustion engine characterized in that the first lock passage and the second lock passage are supplied and discharged from a hydraulic circuit independent of a hydraulic circuit that supplies and discharges hydraulic pressure to and from the advance working chamber and the retard working chamber. Variable valve gear for engine.

1 ... Sprocket (drive rotor)
DESCRIPTION OF SYMBOLS 2 ... Cam shaft 3 ... Phase conversion mechanism 4 ... Hydraulic circuit 5 ... Outer cam shaft 5a ... 1st drive cam 6 ... Inner cam shaft 6a ... 2nd drive cam 8 ... Housing 10 ... 1st vane rotor (1st rotary body)
11a to 11c ... first to third shoes 12 ... retard oil chamber (retard working chamber)
13 ... Advance oil chamber (advance chamber)
DESCRIPTION OF SYMBOLS 14 ... Housing main body 15 ... Front plate 16 ... Rear plate 19 ... 1st rotor 20-22 ... 1st-3rd vane 23 ... 2nd vane rotor (2nd rotary body)
24 ... 2nd rotor 25 ... 4th vane 28 ... 1st lock mechanism 30 ... 1st lock pin 31a * 31b ... 1st lock hole 32 ... 1st pressure receiving chamber 33 ... Coil spring 34 ... 1st release hydraulic circuit 35 ... First release passage 36 ... retard side passage 37 ... advance side passage 38 ... electromagnetic switching valve 39 ... oil pump 39a ... discharge passage 40 ... drain passage 41 ... second lock mechanism 43 ... second lock pin 44 ... second lock Hole 46 ... 1st electromagnetic switching valve 47 ... 2nd release hydraulic circuit 48 ... 2nd release passage 49 ... 2nd electromagnetic switching valve 50 ... 2nd pressure receiving chamber

Claims (3)

An inner camshaft having an inner cam on the outer periphery, and an outer camshaft provided on the outer periphery of the inner camshaft and having an outer cam on the outer periphery. A variable valve operating apparatus for an internal combustion engine that changes a relative rotational phase of the outer cam,
A rotating drive body in which the rotational force is transmitted from the crankshaft and the working chamber is provided inside;
A rotor fixed to one of the camshafts, a vane that divides the working chamber into an advance working chamber and a retard working chamber, and a storage chamber formed therein, and the advance angle A first rotating body that rotates relative to the drive rotating body toward the advance side or the retard angle side by selectively supplying and discharging hydraulic pressure to and from the working chamber and the retard angle working chamber;
A second fixed to the other of the two camshafts and rotatably accommodated in the accommodating chamber, and provided so as to be relatively rotatable by a predetermined angle range with respect to the drive rotator and the first rotator. A rotating body,
A first lock recess provided on a sliding surface of the driving rotating body on which an axial end surface of the second rotating body slides;
The second rotating body is provided so as to be movable along the direction of the rotation axis, and locks the relative rotation between the driving rotating body and the second rotating body by advancing engagement with the first lock recess, and the first lock A first lock member that unlocks the drive rotator and the second rotator by retracting from the recess;
A second lock recess provided at an end of the first lock member opposite to the first lock recess;
The first rotating body is provided so as to be movable along the direction of the rotation axis, and locks relative rotation between the first rotating body and the second rotating body by engaging and advancing into the second lock recess, and the second A second locking member for releasing the lock between the first rotating body and the second rotating body by retracting from the locking recess;
A biasing member that biases the second lock member in the direction of the second lock recess;
By supplying hydraulic fluid, the first lock member is moved backward against the urging force of the urging member together with the second lock member engaged with the second lock dent. A first lock passage for exiting from,
A second lock passage that moves the second lock member away from the first lock member by supplying hydraulic oil, and moves the second lock member away from the second lock recess;
A variable valve operating apparatus for an internal combustion engine, comprising: An inner camshaft having an inner cam on the outer periphery, and an outer camshaft provided on the outer periphery of the inner camshaft and having an outer cam on the outer periphery. A variable valve operating apparatus for an internal combustion engine that changes a relative rotational phase of the outer cam,
A driving rotating body to which the rotational force is transmitted from the crankshaft;
A first rotation that is fixed to one of the camshafts and that can be relatively rotated to the advance side or retard side with respect to the drive rotating body by hydraulic pressure, and in which a storage chamber is formed. Body,
A second fixed to the other of the two camshafts and rotatably accommodated in the accommodating chamber, and provided so as to be relatively rotatable by a predetermined angle range with respect to the drive rotator and the first rotator. A rotating body,
A first lock recess provided on a sliding surface of the driving rotating body on which an axial end surface of the second rotating body slides;
The second rotating body is provided so as to be movable along the direction of the rotation axis, and locks the relative rotation between the driving rotating body and the second rotating body by advancing engagement with the first lock recess, and the first lock A first lock member that unlocks the drive rotator and the second rotator by retracting from the recess;
A second lock recess provided at an end of the first lock member opposite to the first lock recess;
The first rotating body is provided so as to be movable along the direction of the rotation axis, and locks the relative rotation between the first rotating body and the second rotating body by engaging with the second lock recess, and the second lock A second locking member for releasing the lock between the first rotating body and the second rotating body by retracting from the recess;
A biasing member that biases the second lock member in the direction of the second lock recess;
By supplying hydraulic fluid, the first lock member is moved backward against the urging force of the urging member together with the second lock member engaged with the second lock dent. A first lock passage for exiting from,
A second lock passage that moves the second lock member away from the first lock member by supplying hydraulic oil, and moves the second lock member away from the second lock recess;
A variable valve operating apparatus for an internal combustion engine, comprising: An inner camshaft having an inner cam on the outer periphery, and an outer camshaft provided on the outer periphery of the inner camshaft and having an outer cam on the outer periphery. A variable valve operating apparatus for an internal combustion engine that changes a relative rotational phase of the outer cam,
A driving rotating body to which the rotational force is transmitted from the crankshaft;
A first rotation that is fixed to one of the camshafts and that can be relatively rotated to the advance side or retard side with respect to the drive rotating body by hydraulic pressure, and in which a storage chamber is formed. Body,
A second fixed to the other of the two camshafts and rotatably accommodated in the accommodating chamber, and provided so as to be relatively rotatable by a predetermined angle range with respect to the drive rotator and the first rotator. A rotating body,
A first lock mechanism that is provided on the second rotating body and locks or unlocks the relative rotation of the driving rotating body and the second rotating body as required;
A second lock mechanism that is provided on the first rotating body and locks or unlocks the relative rotation of the first rotating body and the second rotating body;
A variable valve operating apparatus for an internal combustion engine, comprising:

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