JP2018096333A - Internal combustion engine valve timing control device and its process of manufacture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a valve timing control device capable of attaining both a light-weight and small-sized configuration of the device.SOLUTION: This invention comprises a sprocket 1 made of a sintered metallic material; a vane rotor 9 fixed to a cam shaft; two pin storing holes 31a, 31b formed in a rotor 15; two lock pins 26, 27 slidably arranged in the pin storing holes; an annular fixing groove 23 arranged at an inside surface 1e of the sprocket; and a lock hole constituting part 28 constituting two lock holes 24, 25 that is fixed in said fixing groove to which an extremity end of each of the lock pins is engaged in when the vane rotor is relatively rotated at a predetermined angular position, the lock hole constituting part being made of a sintered metal having higher hardness than that of the sprocket. The sintered metallic material of the sprocket and the sintered metallic material of the lock hole constituting part are connected through diffusion junction under a state in which the lock hole constituting part is fitted into each of the fixing grooves.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a valve timing control device for an internal combustion engine and a method for manufacturing the same.

  For example, in the conventional valve timing control device described in Patent Document 1 below, in order to reduce the size of the entire device, the outer diameter of the timing sprocket to which the rotational force is transmitted from the crankshaft is reduced, A pin housing hole for housing the lock member is formed near the inner periphery of the rotor portion of the vane rotor.

JP2015-059518A

  However, in the conventional valve timing control device, the cylindrical lock hole constituting portion (sleeve) that forms the lock hole formed in the timing sprocket is formed separately from the drive rotating body, and the timing The sprocket is fixed by being press-fitted into a fixing hole.

  For this reason, in order to ensure the strength of the lock hole component, the outer diameter of the lock hole must be increased, and the outer diameter of the timing sprocket may be increased accordingly.

  Further, in order to secure the strength when the lock hole component is press-fitted and fixed into the fixing hole, the thickness width of the timing sprocket must be relatively large. Therefore, as a result, there is a risk of an increase in the weight of the entire device or an increase in size.

  An object of the present invention is to provide a valve timing control device capable of reducing the weight and size of the entire device.

  As a preferred aspect of the present invention, a recess provided on the inner surface facing the working chamber of the drive rotator, and the vane rotor that is accommodated in the recess and rotated relative to the drive rotator at a predetermined angular position. The lock member has a lock hole into which the tip of the lock member can be inserted, and is formed of a sintered metal having a hardness higher than that of the drive rotating body. The sintered metal material of the drive rotor and the sintered metal material of the lock hole component are mixed and joined in a state in which the hole component is accommodated.

  According to a preferred aspect of the present invention, the valve timing control device can be reduced in weight and size.

It is a disassembled perspective view which shows the principal part of 1st Embodiment of the valve timing control apparatus which concerns on this invention. It is the schematic which shows the hydraulic circuit of the valve timing control apparatus of the embodiment. It is a front view which removes a front plate and shows the state which controlled the valve timing to the retard side by the embodiment. It is a front view which removes a front plate and shows the state which controlled valve timing by the embodiment to the advance side. It is a disassembled perspective view of the sprocket provided to this embodiment, and a lock hole structure part. It is a top view which shows the state which accommodated the lock hole structure part in the groove | channel for fixation of the sprocket, and was fixed by diffusion bonding. It is an expanded sectional view showing operation of each lock pin when the vane rotor provided for this embodiment rotates relatively to the most retarded angle side. FIG. 6 is a developed cross-sectional view showing the operation of each lock pin when the vane rotor rotates slightly from the most retarded angle to the advanced angle side. FIG. 9 is a developed cross-sectional view showing the operation of each lock pin when the vane rotor rotates further from the position shown in FIG. 8 toward the advance side. FIG. 10 is a developed cross-sectional view showing the operation of each lock pin when the vane rotor is rotated further from the position shown in FIG. 9 to an intermediate position. It is an expanded sectional view showing operation of each lock pin when the vane rotor is located at the most advanced angle side. It is a disassembled perspective view which shows the principal part of 2nd Embodiment of this invention. It is a disassembled perspective view of the sprocket provided to this embodiment, and a lock hole structure part. It is a top view which shows the state which accommodated the lock hole structure part in the groove | channel for fixation of the sprocket, and was fixed by diffusion bonding. It is a disassembled perspective view which shows the principal part of 3rd Embodiment of this invention. It is a disassembled perspective view of the sprocket provided to this embodiment, and a lock hole structure part. It is a top view which shows the state which accommodated the lock hole structure part in the groove | channel for fixation of the sprocket, and was fixed by diffusion bonding.

Hereinafter, an embodiment in which a valve timing control device for an internal combustion engine according to the present invention is applied to an intake valve side will be described with reference to the drawings.
[First Embodiment]
1 is an exploded perspective view showing an embodiment of a valve timing control device according to the present invention, FIG. 2 is a schematic diagram showing a hydraulic circuit of the valve timing control device of the embodiment, and FIG. 3 controls the valve timing to the retard side. FIG. 4 is a front view showing the state in which the valve timing according to the embodiment is controlled to the advance side, with the front plate removed.

  That is, as shown in FIGS. 1 and 2, the valve timing control device includes a timing sprocket 1 (hereinafter referred to as a sprocket) that is a driving rotating body that is rotationally driven by a crankshaft of an engine via a timing chain, and an engine. Arranged along the front-rear direction and disposed between the intake-side camshaft 2 provided so as to be relatively rotatable with respect to the sprocket 1 and between the sprocket 1 and the camshaft 2. The phase change mechanism 3 that converts the rotation phase, the first hydraulic circuit 4 that operates the phase change mechanism 3, and the relative rotational position of the camshaft 2 with respect to the sprocket 1 via the phase change mechanism 3 are set on the most retarded side. A position holding mechanism 5 that holds a predetermined intermediate rotational phase position between the rotational position (position in FIG. 3) and the rotational position on the most advanced angle side (position in FIG. 4); A second hydraulic circuit 6 for operating the mechanism 5, and a.

  The sprocket 1 is formed into a thick disk shape by sintered metal formed by compressing and heating iron-based metal powder, and each has a gear around which a timing chain and an auxiliary machine chain are wound. It has two sprocket parts 1a and 1b having a diameter and a small diameter. Further, the sprocket 1 has a support hole 1c, which is an insertion hole rotatably supported on the outer periphery of a vane rotor, which will be described later, fixed to the camshaft 2 in the center.

  The large-diameter sprocket portion 1a has a female screw hole 1d into which four bolts 14 to be described later are screwed at the circumferential position of the outer peripheral portion. The large-diameter sprocket portion 1a is configured as a rear cover that closes a rear end opening of a housing, which will be described later, and performs positioning with a housing body 7a, which will be described later, at a predetermined position on the inner surface 1e that is an inner surface. A pin 1f is projected.

  The camshaft 2 is rotatably supported by a cylinder head (not shown) via a cam bearing, and a plurality of egg-shaped cams that open and close the intake valve are integrally fixed at predetermined positions in the axial direction on the outer periphery. The camshaft 1 has a female screw hole 2b formed in the inner axial direction of the one end 2a.

  As shown in FIGS. 1 to 3, the phase change mechanism 3 is coupled to the sprocket 1 in the axial direction, and is screwed into a housing 7 having an operation chamber inside and a female screw hole 2 b of one end 2 a of the camshaft 2. A vane rotor 9 that is a driven rotating body that is fixed via a cam bolt 8 to be worn and is relatively rotatably accommodated in the housing 7, and four first to fourth shoes 10 a to 10 d that are provided on the inner peripheral surface of the housing 7. And four retarded hydraulic chambers 11 and advanced hydraulic chambers 12, in which the working chambers are separated by the vane rotor 9.

  The housing 7 includes a housing body 7a formed of a sintered metal in a cylindrical shape like the sprocket 1, a front cover 13 formed by press molding and closing the front end opening of the housing body 7a, and a rear cover closing the rear end opening. The housing main body 7a, the front cover 13, and the sprocket 1 are coupled and fixed by four bolts 14 that pass through the bolt insertion holes 10e of the shoes 10 and the like.

  The front cover 13 has an insertion hole 13a formed therethrough in the center, and four bolt insertion holes 13b formed in the circumferential position of the outer periphery.

  The vane rotor 9 is integrally formed of an iron-based genus, and has a rotor 15 fixed to one end 2a of the camshaft 2 by a cam bolt 8, and a radial shape on the outer peripheral surface of the rotor 15 at substantially 120 ° equidistant positions in the circumferential direction. The first to fourth vanes 16a to 16d provided in the first to fourth vanes.

  The rotor 15 is formed in a substantially cylindrical shape that is long in the front-rear direction, and a thin cylindrical insertion guide portion 15a is integrally provided at a substantially central position of the front end surface 15b. In addition, the rotor 15 has a rear end portion 15c extending along the rotation axis direction of the camshaft 2, and a cylindrical fitting groove 15d is formed inside the rear end side.

  On the other hand, as shown in FIGS. 1 and 3, the first to fourth vanes 16 a to 16 d are integrally provided on both sides in the circumferential direction of a pair of large diameter portions 15 e and 15 f that are integrally provided on the outer periphery of the rotor 15. In addition, each is disposed between the shoes 10a to 10d. The vanes 16a to 16d protrude from the large-diameter portions 15e and 15f toward the radially outer side, and have the same circumferential width.

  The large-diameter portions 15e and 15f are formed in an arc shape centered on the axis of the rotor 15 and extend in the radial direction to a substantially central position in the radial direction of the retard and advance hydraulic chambers 11 and 12, which will be described later. The width is substantially uniform.

  In addition, seal members 17a that slide and seal on the inner peripheral surface of the housing body 7a are fitted and fixed in seal grooves formed on the outer surfaces of the respective tip portions of the vanes 16a to 16d. On the other hand, seal members 17b that slide and seal on the outer peripheral surface of the rotor 15 are fitted and fixed in seal grooves formed on the inner peripheral surfaces of the tips of the shoes 10a to 10d.

  As shown in FIG. 3, when the vane rotor 9 rotates relative to the most retarded angle side, the one side surface 16e of the first vane 16a abuts against the opposed side surface of the first shoe 10a and the maximum retarded angle side rotation occurs. When the position is regulated and the relative rotation to the most advanced angle side is performed as shown in FIG. 4, the other side surface 16f of the second vane 16b comes into contact with the opposite side surface of the second shoe 10c facing the rotation position on the maximum advance side. Are now regulated. The first and second vanes 16a and 16b and the first and second shoes 10a and 10c function as mechanical stoppers that regulate the most retarded angle position and the most advanced angle position of the vane rotor 9.

  At this time, the other third and fourth vanes 16c and 16d are in a separated state without coming into contact with the opposing side surfaces of the shoes 10a, 10c, and 10d whose both side surfaces oppose each other in the circumferential direction. Therefore, the contact accuracy between the first and second vanes 16a and 16b and the shoes 10a and 10b is improved, and the supply speed of hydraulic pressure to the hydraulic chambers 11 and 12 to be described later is increased, so that the vane rotor 9 is rotated forward and backward. Responsiveness increases.

  Four retard hydraulic chambers 11 and advance hydraulic chambers 12, which are hydraulic oil chambers, are separated between both side surfaces of the vanes 16a to 16d in the forward / reverse rotation direction and both side surfaces of the shoes 10a to 10d. ing. As shown in FIGS. 3 and 4, each retarded hydraulic chamber 11 and each advanced hydraulic chamber 12 are connected to each other via first communication holes 11 a and second communication holes 12 a formed radially in the rotor 15. The first hydraulic circuit 4 communicates with each other.

  As shown in FIG. 2, the first hydraulic circuit 4 selectively supplies or discharges hydraulic oil (hydraulic pressure) to the retarding and advance hydraulic chambers 11 and 12, as shown in FIG. In addition, each retarded hydraulic chamber 11 is supplied with hydraulic pressure via a first communication hole 11a and a retarded oil passage 18 and each advanced hydraulic chamber 12 is supplied with hydraulic pressure via a second communication hole 12a. The advance oil passage 19 to be discharged, the oil pump 20 which is a fluid pressure supply source for selectively supplying the operation oil to each of the passages 18 and 19, and the retard oil passage 18 and the advance angle according to the operating state of the engine. And a first electromagnetic switching valve 21 for switching the flow path of the oil passage 19.

  The oil pump 20 is a general one such as a trochoid pump that is rotationally driven by an engine crankshaft.

  One end of each of the retard oil passage 18 and the advance oil passage 19 is connected to the passage hole of the first electromagnetic switching valve 21. On the other hand, the other end portions of the respective passages 18 and 19 are retarded passage portions formed along a substantially L-shape in a substantially cylindrical passage constitution portion 37 inserted and held in the insertion guide portion 15a. 18 a and an advance passage portion 19 a formed linearly in the passage configuration portion 37 along the axial direction. The retard passage portion 18a communicates with each retard hydraulic chamber 11 through the first communication hole 11a. On the other hand, the advance passage portion 19a communicates with each advance hydraulic chamber 12 via the oil chamber 19b formed on the head side of the cam bolt 8 and the second communication hole 12a.

  The passage constituting portion 37 is configured as a non-rotating portion with an outer end fixed to a chain cover (not shown). In addition to the passage portions 18a and 19a, the passage constituting portion 37 includes a lock mechanism described later. A passage of the second hydraulic circuit 6 for releasing the lock is formed.

  The first electromagnetic switching valve 21 is a four-port, three-position proportional valve, and is slidable in the axial direction in a valve body (not shown) by a pulse current output from a control unit (not shown). The spool valve body is moved in the front-rear direction. Accordingly, the discharge passage 20a of the oil pump 20 and one of the oil passages 18 and 19 are communicated with each other, and at the same time, the other oil passages 18 and 19 and the drain passage 22 are communicated.

  The suction passage 20 b and the drain passage 22 of the oil pump 20 communicate with the oil pan 52. In addition, a filter 50 is provided on the downstream side of the discharge passage 20a of the oil pump 20, and communicates with a main oil gallery M / G that supplies lubricating oil to a sliding portion of the internal combustion engine on the downstream side. doing. Further, the oil pump 20 is provided with a flow rate control valve 51 that discharges excess hydraulic oil discharged from the discharge passage 20a to the oil pan 52 and controls the flow rate to an appropriate flow rate.

  In the control unit, an internal computer detects a current rotation phase of a crank angle sensor (engine speed detection), an air flow meter, an engine water temperature sensor, an engine temperature sensor, a throttle valve opening sensor, and a camshaft 2 (not shown). Information signals from various sensors such as a cam angle sensor are input to detect the current engine operating state. The control unit outputs a control pulse current to each electromagnetic coil of the first electromagnetic switching valve 21 and the second electromagnetic switching valve 36, which will be described later, and controls the movement position of each spool valve body to switch each passage. It is supposed to be controlled.

  Further, in this embodiment, the vane rotor 9 is rotated with respect to the housing 7 by a predetermined intermediate rotation between the most retarded rotation position (position in FIG. 3) and the most advanced rotation position (position in FIG. 4). A position holding mechanism 5 that holds the phase position is provided.

  As shown in FIGS. 1 to 3, the position holding mechanism 5 is housed and fixed in a fixing groove 23 that is a recess provided in the inner peripheral portion of the inner surface 1 e of the large-diameter sprocket portion 1 a of the sprocket 1. Provided in the direction of the internal axis of the lock hole constituting portion 28, the first and second lock holes 24 and 25 which are lock recesses formed in the lock hole constituting portion 28, and the large diameter portions 15e and 15f of the rotor 15, respectively. First and second pin receiving holes 31a and 31b, and two lock members which are slidably provided in the respective pin receiving holes 31a and 31b and are respectively engaged with and disengaged from the respective lock holes 24 and 25. 1 and second lock pins 26 and 27, and a second hydraulic circuit 6 (see FIG. 1) for releasing the engagement of the lock pins 26 and 27 with respect to the lock holes 24 and 25.

  The fixing groove 23 is formed in an annular shape along the hole edge on the inner surface 1e side of the support hole 1c of the sprocket 1, and the inner peripheral portion is continuous with the inner peripheral surface of the support hole 1c in the axial direction. The fixing groove 23 has a groove depth set to about half the thickness width of the large-diameter sprocket portion 1a and an inner diameter D formed to a predetermined width. In other words, the inner diameter D is set in relation to the lock holes 24 and 25 of the lock hole constituting portion 28, and the lock holes 24 and 25 are located approximately at the center in the radial direction via the lock hole constituting portion 28. It is set to such a size.

  The lock hole constituting portion 28 is formed in an annular shape from a sintered metal like the sprocket 1, but is formed so that its hardness is higher than that of the sprocket 1. That is, the lock hole constituting portion 28 has a sintered hardness higher than that of the sprocket 1 by, for example, making the metal powder density higher than that of the sprocket 1 at the time of sintering.

  The lock hole constituting portion 28 is formed so that the axial thickness is substantially the same as the groove depth of the fixing groove 23, and the outer diameter of the outer peripheral surface 28 a is the inner diameter of the inner peripheral surface 23 a of the fixing groove 23. It is formed almost the same. As a result, when the lock hole constituting portion 28 is inserted into the fixing groove 23 during sintering molding, the outer peripheral surface 28a is in close contact with the inner peripheral surface 23a of the fixing groove 23, that is, close to press-fitting. It is arranged to be placed in close contact with the state. Further, the inner diameter of the inner peripheral surface 28b is formed substantially the same as the inner diameter D1 of the support hole 1c.

  As shown in FIGS. 2, 5, and 11, the first lock hole 24 is formed in a long groove shape along the circumferential direction of the lock hole constituting portion 28, and the bottom surface is advanced from the retarded side to the advanced side. It is formed in a two-step staircase shape. In other words, the inner side surface 1e of the sprocket 1 is the uppermost step, and the first bottom surface 24a and the second bottom surface 24b that are lowered step by step are formed in a stepped shape that is sequentially lowered, and each inner side surface on the retard side rises vertically. It is a wall surface. Further, the inner side surface 24c on the advance side of the second bottom surface 24b is also a wall surface rising vertically.

  The area of the first bottom surface 24 a is set smaller than the area of the distal end surface of the distal end portion 26 b of the first lock pin 26. On the other hand, the second bottom surface 24 b extends slightly in the circumferential direction (advance direction), and the area thereof is set to be larger than the tip surface of the first lock pin 26.

  Therefore, the second bottom surface 24 b is an intermediate position closer to the advance side than the rotational position of the vane rotor 9 on the inner surface 1 e of the sprocket 1 on the most retarded side.

  The second lock hole 25 is formed concentrically with the first lock hole 24 and in a circular shape on the upper surface side of the lock hole forming portion 28. Further, the bottom surface 25a is formed in a flat shape with no step, and is formed at an intermediate position on the inner surface 1e of the sprocket 1 that is shifted from the rotational position on the advance side of the vane rotor 9 to the retard side. The second lock hole 25 is a wall surface that vertically rises on each inner side surface on the advance side, and a wall surface that also rises vertically on the inner side surface 25b on the retard side. Since the outer diameter of the distal end portion 27b of the second lock pin 27 is smaller than the inner diameter of the second lock hole 25, the second lock pin 27 is engaged with the second lock pin 27 through the circumferential clearance. It is possible to move slightly to the advance side.

  The first lock hole 24 and the second lock hole 25 are also configured as a release pressure receiving chamber into which the operating hydraulic pressure is introduced from the second hydraulic circuit 6, and the hydraulic pressure introduced here is used as the first and second locks. It is made to act simultaneously on the tip surfaces of the tip portions 26b, 27b of the pins 26, 27 and first and second step surfaces 26c, 27c (pressure receiving surfaces) of first and second lock pins 26, 27 described later. ing.

  The first lock pin 26 is slidably disposed in a first pin receiving hole 31a formed through the large diameter portion 15e of the rotor 15 in the inner axial direction as shown in FIGS. The pin main body 26a and a small-diameter first front end portion 26b integrally provided on the front end side of the pin main body 26a via a first step surface 26c.

  The first pin body 26a is formed in a simple straight cylindrical surface on the outer peripheral surface, and is configured to slide in a liquid-tight manner in the first pin housing hole 31a, while the first tip portion 26b has a small diameter. The outer diameter is set to be smaller than the inner diameter of the first lock hole 24.

  The first lock pin 26 has a spring force of a first spring 29 that is an urging member that is elastically mounted between a bottom surface of a groove formed in the inner axial direction from the rear end side and the inner surface of the front cover 13. Is biased in a direction to engage with the first lock hole 24.

  The first step surface 26 c is formed in an annular shape and functions as a pressure receiving surface that receives hydraulic pressure introduced from a communication passage 39 described later, and the first lock pin 26 is resisted against the spring force of the first spring 29. The lock is released by retreating from the first lock hole 24.

  In addition, when the vane rotor 9 rotates from the most retarded position to the advanced angle side, the first lock pin 26 has the first tip portion 26b at each bottom surface of the first lock hole 24 as shown in FIGS. Further advancement of the vane rotor 9 is achieved when the side edge of the tip end portion 26b finally comes into contact with the inner side surface 24c on the advance side while slidingly contacting the second bottom surface 24b while engaging with the stepped portions 24a and 24b. Angular rotation is restricted. Specifically, it will be described in the section of the operation of the present embodiment.

  The second lock pin 27 has an overall outer shape such as an outer diameter and a length that is substantially the same as that of the first lock pin 26, and is a second pin that is formed through the large-diameter portion 15 f of the rotor 15. The pin main body 27a is slidably disposed in the receiving hole 31b, and a small-diameter columnar front end portion 27b integrally provided on the front end side of the pin main body 27a via the second step surface 27c. Yes.

  The pin body 27a is formed in a simple straight cylindrical surface on the outer peripheral surface, and slides in a liquid-tight manner on the second pin accommodation hole 31b. On the other hand, the distal end portion 27 b is formed in a substantially cylindrical shape with a small diameter, and the outer diameter is set smaller than the inner diameter of the second lock hole 25.

  The second lock pin 27 has a spring force of a second spring 30 that is an urging member that is elastically mounted between the bottom surface of the groove formed in the inner axial direction from the rear end side and the inner surface of the front cover 13. Is biased in a direction to engage with the second lock hole 25.

  The second step surface 27c is formed in an annular shape and functions as a pressure receiving surface that receives hydraulic pressure introduced from a communication passage 39 described later. That is, the second lock pin 27 is retracted from the second lock hole 25 against the spring force of the second spring 30 to release the lock.

  As shown in FIG. 2, the front cover 13 is a circle that communicates the first and second pin receiving holes 31a and 31b with the atmosphere to ensure smooth sliding of the first and second lock pins 26 and 27. Arc-shaped first and second breathing grooves 32a and 32b are formed.

  Further, when the vane rotor 9 rotates from the most retarded position to the advanced side, the second lock pin 27 is slidably in contact with the inner side surface 1e of the sprocket 1 as shown in FIGS. The front end surface is brought into elastic contact with the bottom surface 25 a by engaging with the second lock hole 25. At this time, when the side edge of the tip 27b comes into contact with the inner side surface 25b on the retard side, the further rotation of the vane rotor 9 in the retard direction is restricted.

  Then, at the engagement position of the second lock pin 27, as shown in FIG. 10, the first lock pin 26 is also engaged with the first lock hole 24 so that the side edge of the tip end portion 26b is on the inner side of the second bottom surface 24b. It is in a state of being in contact with the side surface 24c. For this reason, the first lock pin 26 and the second lock pin 27 sandwich the portion between the lock holes 24 and 25, and the free rotation of the vane rotor 9 to the advance side and the retard side is restricted. It is supposed to be.

  That is, the first and second lock pins 26 and 27 are simultaneously engaged with the corresponding first and second lock holes 24 and 25, respectively, so that the vane rotor 9 and the housing 7 have the most retarded phase and the maximum phase. It is held at an intermediate phase position between the advance angle phase.

  As shown in FIG. 10, in a state where both lock pins 26 and 27 are engaged with the respective lock holes 24 and 25, the first and second step surfaces 26 c and 27 c are the upper end holes of the respective lock holes 24 and 25. It is formed so as to be slightly above the edge.

  As shown in FIG. 1, the second hydraulic circuit 6 supplies hydraulic pressure to the first and second lock holes 24 and 25 via a supply passage 34 branched from the discharge passage 20a of the oil pump 20. It has become. Further, the second hydraulic circuit 6 has a supply / discharge passage 33 that discharges the hydraulic oil in the first and second lock holes 24 and 25 through a discharge passage 35 communicating with the drain passage 22 and the state of the engine. A supply / discharge passage 33 and a second electromagnetic switching valve 36 as a second control valve for selectively switching the passages 34 and 35 are provided.

  As shown in FIGS. 1 and 2, the supply / discharge passage 33 is connected at one end to a corresponding passage hole of the second electromagnetic switching valve 36. On the other hand, the supply / discharge passage portion 33 a on the other end side is formed by branching from the inner axial direction of the passage constituting portion 37 in the radial direction, and is formed with a pair of oil passages 38 and a pair of communication passages formed inside the rotor 15. 39, the lock holes 24 and 25 communicate with each other.

  The passage constituting portion 37 is formed with a plurality of annular fitting grooves at front and rear positions in the axial direction of the outer peripheral surface. In each of the fitting grooves, three seal rings 40 for sealing the opening ends of the retard passage portion 18a and the supply / discharge passage portion 33a, one end side of the oil chamber 19b, and the like are fitted and fixed, respectively.

  As shown in FIGS. 3 and 7, each oil passage 38 is formed inside each large diameter portion 15 e, 15 f, and each radial passage portion 38 a drilled along the radial direction of the rotor 15. And axial passage portions 38b that are drilled along the axial direction and connected to substantially the center position of the radial passage portions 38a.

  Each radial passage portion 38a is formed to penetrate in the radial direction by drilling, and the outer peripheral side end portion is closed by a ball stopper not shown.

  As shown in FIGS. 3 and 7, etc., each communication passage 39 is cut out in a substantially arc shape on the front end surface of the rotor 15, and the formation position thereof is on the inner peripheral surface of each large diameter portion 15e, 15f. It is formed at a sufficiently close position.

  In addition, each communication passage 39 has a length in the circumferential direction at any relative rotational position of the vane rotor 9 between the first end 39a and the other end 39b. It is formed so as to face the hole 25, and always communicates therewith.

  Each communication passage 39 faces the tip of the first and second pin housing holes 31a and 31b. That is, the communication path 39 is always the first and second step surfaces at any rotational position from the most retarded rotation position (FIG. 7) to the most advanced rotation position (FIG. 11). 26c, 27c and the first and second lock holes 24, 25. Further, one end portion 39a of each communication passage 39 communicates with the above-described axial passage portion 38b.

  The second electromagnetic switching valve 36 is a three-port two-position on-off type valve, and is connected to the supply / exhaust passage 33 and the passage by a spool valve body by the control current output from the control unit and the spring force of the internal valve spring. One of 34 and 35 is selectively communicated.

  The lock hole constituting portion 28 is joined to the fixing groove 23 of the sprocket 1 by so-called diffusion joining.

  That is, as shown in FIG. 5, the sprocket 1 previously formed of sintered metal is fixed by a predetermined fixing jig with the inner surface 1e of the large-diameter sprocket portion 1a facing upward.

  After that, as shown in FIG. 6, the lock hole forming portion 28 formed in advance by sintered metal having high hardness is positioned horizontally in the fixing groove 23 from above the large-diameter sprocket portion 1a. While maintaining the posture, the outer peripheral surface 28a is pushed in at a predetermined pressure while being in sliding contact with the inner peripheral surface 23a of the fixing groove 23. Therefore, in the fully pushed-in state, the outer peripheral surface 28 a of the lock hole constituting portion 28 and the inner peripheral surface 23 a of the fixing groove 23 are in close contact with each other.

  Subsequently, the sprocket 1 and the lock hole component 28 are pressurized in a controlled atmosphere such as vacuum or in an inert gas, and heated at a temperature below the melting point of the sprocket 1 and the lock hole component 28. Then, atoms are diffused and bonded to the bonding surface between the fixing groove 23 and the inner and outer peripheral surfaces 23a of the lock hole forming portion 28 in a mixed state.

Therefore, if these are taken out after cooling, the lock hole constituting portion 28 is firmly fixed and integrated in the fixing groove 23 of the sprocket 1.
[Operation of this embodiment]
Hereinafter, the operation of the present embodiment will be described.

  When the ignition switch is turned off to stop the engine, a control current is output from the control unit to the first electromagnetic switching valve 21 immediately before the engine is completely stopped. With this control current, the spool valve body is moved in one axial direction so as to communicate with one of the discharge passage 20a and the retard oil passage 18 or the advance oil passage 19, and the drain passage 22 and one of the other oil passages. 18 and 19 are made to communicate. That is, the control unit detects the current relative rotational position of the vane rotor 9 based on the information signal from the cam angle sensor or the crank angle sensor, and based on this, the respective retarded hydraulic chambers 11 or the advanced hydraulic chambers are detected. 12 is supplied with hydraulic pressure. Thus, the vane rotor 9 is controlled to rotate to a predetermined intermediate position between the most retarded angle side and the most advanced angle side.

  At the same time, the second electromagnetic switching valve 36 is energized to connect the supply / discharge passage 33 and the discharge passage 35. As a result, the hydraulic oil in the first and second lock holes 24, 25 flows from the supply / discharge passage 33 into the discharge passage 35 and the drain passage 22 via the communication passage 39 and the oil passage 38 and enters the oil pan 52. It is discharged and becomes low pressure. Therefore, as shown in FIG. 10, the lock pins 26 and 27 are urged in the advancing direction (direction to engage with the lock holes 24 and 25) by the spring force of the springs 29 and 30. , 25 respectively.

  In this state, the outer side surface of the tip end portion 26b of the first lock pin 26 abuts against the opposed inner side surface 24c on the advance side of the first lock hole 24, and movement in the retard direction is restricted. On the other hand, the outer side surface of the distal end portion 27b of the second lock pin 27 abuts against the opposite inner side surface 25b of the second lock hole 25 on the retard side, and movement in the retard direction is restricted.

  By this operation, the vane rotor 9 is held at the intermediate phase position, and the valve closing timing of the intake valve is controlled to the advance side before the piston bottom dead center.

  Therefore, when the engine is restarted in a cold state after a sufficient amount of time has elapsed since the engine stopped, the engine's effective compression ratio is increased due to the specific closing timing of the intake valve, combustion is improved, and starting is stabilized and started. Can improve the performance.

  Thereafter, when the engine shifts to idling operation, the first electromagnetic switching valve 21 communicates the discharge passage 20a and the retarded oil passage 18 with the control current output from the control unit, and the advance hydraulic chamber 19 and the drain passage 22 are communicated. To communicate. On the other hand, at this time, the second electromagnetic switching valve 36 is not energized from the control unit, the supply / discharge passage 33 and the supply passage 34 are communicated, and the discharge passage 35 is closed.

  Therefore, the hydraulic pressure discharged from the oil pump 20 into the discharge passage 20 a flows into the communication passage 39 through the supply passage 34, the supply / discharge passage 33 and the oil passage 38. Further, the hydraulic pressure acts on the first and second step surfaces 26c, 27c as pressure receiving surfaces of the lock pins 26, 27 while flowing into the lock holes 24, 25 from here.

  Accordingly, the lock pins 26 and 27 are retracted against the spring force of the springs 29 and 30, and the tip portions 26b and 27b are pulled out from the lock holes 24 and 25, and the lock is released. Thereby, the vane rotor 9 is ensured to rotate freely.

  Further, a part of the hydraulic pressure discharged to the discharge passage 20a is supplied to each retarded hydraulic chamber 11 through the retarded passage portion 18a and each first oil passage 11a, while the operation of each advanced hydraulic chamber 12 is performed. Oil is discharged from the drain passage 22 to the oil pan 52 through each second communication hole 12a and the advance passage portion 19a.

  Therefore, the inside of each retarded hydraulic chamber 11 becomes high pressure, while the inside of each advanced hydraulic chamber 12 becomes low pressure. Therefore, as shown in FIG. 3, the vane rotor 9 rotates to the left side (retard side) in the drawing, and one side surface of the first vane 16a comes into contact with the opposite side surface of the first shoe 10a, and the most retarded side. The rotation position is regulated and held.

  As a result, the valve overlap between the intake valve and the exhaust valve is eliminated, the combustion gas is prevented from being blown back, a good combustion state is obtained, and the fuel consumption is improved and the engine rotation is stabilized.

  In addition, when the engine is in a high rotation range, for example, the first electromagnetic switching valve 21 switches the flow path by the control current output from the control unit, as shown in FIG. The oil passage 19 is connected, and the retard hydraulic chamber 18 and the drain passage 22 are connected. On the other hand, at this time, the state where the second electromagnetic switching valve 36 connects the supply / discharge passage 33 and the supply passage 34 and the discharge passage 35 is closed is continued.

  Therefore, this time, each advance hydraulic chamber 12 becomes high pressure and each retard hydraulic chamber 11 becomes low pressure. Therefore, as shown in FIG. 4, the vane rotor 9 rotates to the advance side, and the other side surface of the first vane 16a abuts against the opposite side surface of the second shoe 10b and is held at the most advanced side rotation position. Is done. As a result, the opening timing of the intake valve is advanced, the valve overlap with the exhaust valve is increased, the intake air amount is increased, and the output is improved.

  As described above, when the ignition switch is turned off to stop the engine, the vane rotor 9 does not return to the intermediate position between the most retarded angle side and the most advanced angle side that is difficult to restart the engine for some reason. In addition, for example, when the rotation is stopped at the most retarded position as shown in FIG.

  That is, when cranking is started by turning on the ignition switch, positive and negative alternating torque generated due to the spring force of the valve spring is input to the camshaft 2 (vane rotor 9) in the initial stage of cranking. The Since the vane rotor 9 is slightly rotated toward the advance side when a negative torque is input from among the fluctuating torque, the tip end portion 26b of the first lock pin 26 is connected to the first spring as shown in FIG. The spring force 29 lowers and contacts the first bottom surface 24 a of the first lock hole 24.

  Immediately after that, when a positive torque is input and a rotational force is applied to the vane rotor 9 toward the retard side, the outer surface of the tip portion 26b of the first lock pin 26 contacts the rising inner surface 24d on the first bottom surface 24a side. Contact and rotation to the retard side is regulated. Thereafter, when negative torque is applied again, the leading end portion 26b of the first lock pin 26 descends to the second bottom surface 24b and engages with the rotation of the vane rotor 9 toward the advance side as shown in FIG.

  Here, when a positive torque is applied again, the outer surface of the tip end portion 26b comes into contact with the rising inner surface 24e on the second bottom surface side, and the rotation to the retarded angle side is restricted. That is, the vane rotor 9 automatically and sequentially rotates toward the advance side by the ratchet function between the first lock pin 26 and the first lock hole 24.

  Subsequently, when the vane rotor 9 is again rotated to the advance side by the negative torque, the first lock pin 26 has the tip 26b advanced on the second bottom surface 24b of the first lock hole 24 as shown in FIG. The outer peripheral surface of the tip end portion 26b contacts the advance side inner surface 24c. At the same time, the second lock pin 27 engages in the second lock hole 25 so that the front end portion 27b contacts the bottom surface 25a, and the outer surface of the front end portion 27b contacts the inner surface 25b on the retard side. As a result, the opposing portions are sandwiched by the tip portions 26b, 27b of the first lock pin 26 and the second lock pin 27. Therefore, the vane rotor 9 is automatically held at an intermediate position between the most retarded angle side and the most advanced angle side, and free rotation to the advanced angle side and the retarded angle side is restricted.

  Therefore, at the time of the normal cold start, the effective compression ratio of the engine during cranking is increased and combustion is improved, so that the start can be stabilized and the startability can be improved.

  As described above, in the present embodiment, the first and second step surfaces 26c and 27c on the distal end portions 26b and 27b side of the first and second lock pins 26 and 27 are used as pressure receiving surfaces for release. The outer peripheral surfaces of the pin bodies 26a and 27a can be formed into a substantially straight cylindrical surface. Therefore, the outer diameters of the lock pins 26 and 27 can be made as small as possible, so that the entire apparatus including the rotor 15 can be made compact. As a result, the mountability to the engine in the engine room is improved.

  By the way, in the valve timing control device, each of the lock holes 24 and 25 has a sliding resistance due to engagement of the lock pins 26 and 27 and a positive input from the camshaft 2 being engaged (locked). An input load in the shearing direction due to contact of the tip portions 26b, 27b of the lock pins 26, 27 due to negative alternating torque acts. Therefore, the formation site of the lock holes 24, 25, that is, the lock hole constituting portion 28 needs to have a strength (hardness) higher than the hardness of the sprocket 1.

  Therefore, in the conventional technique, the outer diameter is increased in order to ensure the strength of the lock hole component (sleeve), and the outer diameter of the timing sprocket must be increased accordingly. Further, in order to ensure the strength when the lock hole component having an enlarged outer diameter is press-fitted and fixed into the fixing hole, the wall thickness of the timing sprocket has to be relatively large. For this reason, there existed a possibility that the increase in the weight of the whole apparatus and an enlargement might be forced.

  On the other hand, in this embodiment, the high-strength lock hole constituting portion 28 is fixed not by press-fitting into the fixing groove 23 of the sprocket 1 but by diffusion bonding. That is, since the lock hole forming portion 28 is joined to the fixing groove 23 of the sprocket 1 by diffusion bonding, a large press-fitting allowance for the conventional press fitting is not required, and the lock hole forming portion 28 itself is large. It is not necessary to increase the diameter or the thickness of the sprocket 1. For this reason, technical problems, such as the increase in the weight of the whole apparatus like the prior art, and an enlargement, can be eliminated.

  In other words, since the bonding structure for the fixing groove 23 is diffusion bonded while ensuring the strength of the lock hole constituting portion 28, the entire apparatus can be reduced in size and weight.

  Moreover, in the present embodiment, as described above, even if the sintered metal is the same, the hardness of the lock hole constituting portion 28 is higher than the hardness of the sprocket 1, so that the alternating torque of the camshaft 2 is increased. Even if it acts, chipping of the hole edges of the lock holes 24 and 25 is suppressed, and sufficient durability can be obtained.

  Further, it is conceivable to directly form a lock hole on the inner surface 1e of the large-diameter sprocket 1a of the sprocket 1 without using the lock hole constituting portion 28. In this case, however, the hardness of the sprocket 1 is low. There is a risk that the required strength will be insufficient. As a result, the large input load from the timing chain cannot be endured, and the durability may be reduced.

On the other hand, in the present embodiment, the lock hole is not directly formed in the sprocket 1, but the hardness of the lock hole constituting portion 28 separate from the sprocket 1 is higher than the hardness of the sprocket 1 as described above. Therefore, the strength of the sprocket 1 is not affected.
[Second Embodiment]
12 to 14 show a second embodiment, in which two fixing grooves 43 and 44 of the sprocket 1 formed of a sintered alloy are provided on the inner peripheral portion of the sprocket 1, and both the fixing grooves 43 are provided. 44, two lock hole constituting portions 45, 46 are accommodated and fixed.

  Specifically, the first and second fixing grooves 43 and 44 are formed at symmetrical positions on the straight line of the inner surface 1e of the large-diameter sprocket portion 1a, and each is formed in a rectangular shape. Yes. Each of the fixing grooves 43 and 44 has an inner end facing the hole edge of the support hole 1c, and has a radial length substantially the same as the width of the fixing groove 23 of the first embodiment.

  The first fixing groove 43 is formed in a quadrangular shape in which the length of each side is substantially equal, whereas the second fixing groove 44 is formed in a rectangular shape extending in the lateral direction.

  The first and second lock hole constituting portions 45 and 46 are formed of a sintered metal whose hardness is higher than that of the sprocket 1 and are rectangular blocks similar to the first and second fixing grooves 43 and 44. It is formed in a shape. A circular first lock hole 24 is formed substantially at the center of the first lock hole constituting portion 45, while an elliptical first extending in the lateral direction is substantially located at the center of the second lock hole constituting portion 46. Two lock holes 25 are formed. The structure of the first and second lock holes 24 and 25 is the same as that of the first embodiment.

  The first and second lock hole constituting portions 45 and 46 are formed to be substantially the same as the inner shapes of the first and second fixing grooves 43 and 44 corresponding to the entire outer shape including the thickness and the like of each. Yes. Further, as shown in FIG. 14, when the lock hole constituting portions 45 and 46 are accommodated in the fixing grooves 43 and 44, the respective side surfaces 45 a, 45 b, 46 a and 46 b are respectively connected to the fixing grooves 43. , 44 are in contact with each of the opposing inner side surfaces 43a, 43b, 44a, 44b. The inner end surfaces 45c and 46c of the lock hole constituting portions 45 and 46 are formed in an arc shape along the inner peripheral surface of the support hole 1c.

  And in order to carry out the diffusion joining of the 1st, 2nd lock hole structure parts 45 and 46 in the 1st, 2nd fixing grooves 43 and 44, as shown in FIG. 13, it shape | molded previously with the sintered metal. The sprocket 1 is fixed with a predetermined fixing jig with the inner surface 1e of the large-diameter sprocket portion 1a facing upward.

  Thereafter, as shown in FIG. 14, the lock hole components 45 and 46 formed in advance with a sintered metal having a high hardness are positioned in the fixing grooves 44 and 44 from above and maintained in a horizontal posture. While pushing the both side surfaces 45a, 45b, 46a, 46b to the opposing inner side surfaces 43a, 43b, 44a, 44b of the fixing grooves 43, 44, they are pushed in at a predetermined pressure. Therefore, in the state where it is completely pushed in and accommodated, each lock hole constituting portion 45, 46 has its opposite side surfaces 45a, 45b, 46a, 46b and each of the opposing inner side surfaces 43a, 43b, 44a, 44b of the fixing grooves 43, 44. It is in close contact.

  At this time, a minute clearance is formed between the inner end face outside each fixing groove 44, 45 and the outer end face of each lock hole constituting portion 45, 46 facing the inner end face. Yes.

  Subsequently, the sprocket 1 and the lock hole constituent portions 45 and 46 are pressurized in a controlled atmosphere such as vacuum or in an inert gas, and heated at a temperature below the melting point of the sprocket 1 and the lock hole constituent portion 28. To do. Then, atoms are mixed in the joint surfaces between the opposing inner side surfaces 43a, 43b, 44a, 44b of the fixing grooves 43, 44 and the side surfaces 45a, 45b, 46a, 46b of the lock hole constituting portions 45, 46. Diffused and joined.

  Therefore, if it takes out after these cooling, each lock-hole structure part 45 and 46 will be in the state firmly joined and integrated in each fixing groove 43 and 44 of the sprocket 1. FIG.

Therefore, in this embodiment, the same operational effects as those of the first embodiment described above can be obtained, and two each of the fixing grooves 43 and 44 and the two lock hole constituting portions 45 and 46 are provided. , The degree of freedom in forming is improved.
[Third Embodiment]
FIGS. 15 to 17 show the third embodiment, in which the fixing grooves 43 and 44 and the lock hole constituting portions 45 and 46 in the second embodiment are formed in a circular arc shape.

  That is, each of the fixing grooves 43 and 44 is formed in a shape of a larger diameter toward the outer peripheral side with the inner peripheral side as a main side, and is formed in an arc fan shape as a whole.

  On the other hand, each lock hole component 45, 46 is formed in a similar shape to each of the fixing grooves 43, 44, and is formed in an arc fan shape as a whole.

  The sprocket 1 and the lock hole constituent portions 45 and 46 are made of the same sintered metal, but the hardness of the lock hole constituent portions 45 and 46 is higher.

  Further, as shown in FIG. 17, when the lock hole constituting portions 45 and 46 are accommodated in the fixing grooves 43 and 44, the respective side surfaces 45a, 45b, 46a and 46b in the circumferential direction are fixed. The grooves 43 and 44 are in contact with the opposing inner side surfaces 43a, 43b, 44a and 44b in close contact with each other.

  And in order to carry out the diffusion joining of the 1st, 2nd lock hole structure parts 45 and 46 within the 1st, 2nd fixing grooves 43 and 44, it is performed by the same formation process as 2nd Embodiment. That is, as shown in FIG. 16, the sprocket 1 previously formed of sintered metal is fixed by a predetermined fixing jig with the inner surface 1e of the large-diameter sprocket portion 1a facing upward. After that, since it is the same as the process mentioned above, description is abbreviate | omitted.

  Therefore, this embodiment can obtain the same operation effect as the second embodiment, and the circumferential length of each of the fixing grooves 43 and 44 and the lock hole constituting portions 45 and 46 depends on the specification and size of the apparatus. It is possible to change it freely.

  The present invention is not limited to the configuration of the above embodiment, and the valve timing control device can be applied not only to the intake side but also to the exhaust side.

  In each of the above-described embodiments, two lock holes and two lock pins are shown. However, even if one lock hole or two lock pins are provided, the present invention can be applied to one provided with two or more lock holes or lock pins. It is.

  As the drive rotor, not only the sprocket 1 but also the pulley can be applied. Furthermore, it is also possible to freely change the shape of the fixing groove and the lock hole constituting portion, the arrangement position, and the like.

  Furthermore, the present apparatus can be applied to a so-called idle stop vehicle or a so-called hybrid vehicle in which the drive source is switched between an electric motor and an internal combustion engine depending on the travel mode of the vehicle.

  In addition, the lock hole component is not limited to a metal powder density higher than that of the sprocket at the time of sintering molding, for example, the material of the lock hole component can be made to be harder than the material of the sprocket. is there.

  As a valve timing control device for an internal combustion engine based on the embodiment described above, for example, the following modes can be considered.

In one aspect thereof, the rotational force transmitted from the crankshaft is transmitted, and a driving rotary body formed of sintered metal having a working chamber therein,
A rotor fixed to the camshaft and a vane rotor provided on the outer periphery of the rotor and having a vane that divides the working chamber into a plurality of parts;
A pin receiving hole formed in the vane rotor along the rotational axis direction of the camshaft;
A lock member slidably disposed in the pin accommodation hole;
A recessed portion provided on an inner surface of the driving rotating body facing the working chamber;
The drive rotator has a lock hole that is housed in the recess and into which the tip of the lock member can be engaged when the vane rotor rotates relative to the drive rotator at a predetermined angular position. A lock hole component formed of sintered metal having higher hardness,
With
The sintered metal material of the drive rotating body and the sintered metal material of the lock hole component are mixed and joined in a state where the lock hole component is accommodated in the recess.

  As a more preferable aspect, the joining by mixing the sintered metal material of the drive rotating body and the sintered metal material of the lock constituent portion is diffusion bonding.

  As a more preferred aspect, the drive rotator has an insertion hole into which a part of the rotor is inserted, and the recess is formed at a hole edge on the inner surface side of the insertion hole.

  As a more preferable aspect, the lock hole constituting portion accommodated in the recess has an inner peripheral surface formed in an arc shape along the inner peripheral surface of the insertion hole.

  As a more preferable aspect, the concave portion is formed in an annular groove shape along the entire hole edge of the insertion hole.

  As a more preferable aspect, the lock hole constituting part is formed in an annular shape following the shape of the concave part.

  As a more preferred aspect, the recess is formed in an annular groove shape along the entire hole edge of the insertion hole, and the lock hole constituting portion is formed in an annular shape following the shape of the recess. In a state where the hole constituting portion is accommodated and held in the recess, the outer peripheral surface of the lock hole constituting portion and the inner peripheral surface of the recess facing the outer peripheral surface in the radial direction are in close contact.

  As a more preferable aspect, the concave portion is formed in a rectangular groove shape extending radially outward from a hole edge of the insertion hole.

  As a further preferred aspect, the lock hole constituting portion is formed in a rectangular shape following the shape of the recess, and both sides in the circumferential direction of the drive rotator are in the circumferential direction of the drive rotator of the recess. Are in close contact with the opposite inner surface.

  As a more preferred aspect, the recess is formed in a fan groove shape extending in the circumferential direction along a hole edge of the insertion hole, and the lock hole constituting portion has a fan shape following the shape of the recess. Thus, both side surfaces of the drive rotator in the circumferential direction are in close contact with the inner surfaces of the recesses facing in the circumferential direction of the drive rotator.

As another preferred aspect, a driving rotating body formed of a sintered metal to which a rotational force from the crankshaft is transmitted and having a working chamber therein,
A rotor fixed to the camshaft; a vane provided on an outer periphery of the rotor to divide the working chamber into a plurality of parts; and a pin accommodation hole formed in the rotor or the vane along a rotation axis direction of the rotor. A vane rotor having,
A lock member slidably provided in the pin accommodation hole;
A recess provided on an inner surface facing the working chamber of the drive rotor;
A lock hole constituting portion that is housed and disposed in the recess, constitutes a lock hole into which the tip of the lock member can be engaged, and is formed of a sintered metal having a hardness higher than that of the drive rotating body,
A method for manufacturing a valve timing control device for an internal combustion engine comprising:
The lock hole component is accommodated in the recess and held in the recess,
Thereafter, in a state where the lock hole component is housed and held in the recess, the lock hole component is pressurized and heated to diffusely bond the outer surface of the lock hole component and the inner surface of the recess in contact with the outer surface. Joined by.

  As a more preferred aspect, the drive rotator has an insertion hole into which a part of the rotor is inserted, and the recess is formed at a hole edge on the inner surface side of the insertion hole.

  As a further preferred aspect, the inner surface of the lock hole constituting portion is formed in an arc shape along the inner peripheral surface of the insertion hole, and then the lock hole constituting portion is accommodated and held in the concave portion. In this state, the lock component was joined into the recess by diffusion bonding.

As a further preferred embodiment, the recess is formed in an annular groove shape along the entire hole edge of the insertion hole,
The lock hole component is formed in an annular shape following the shape of the recess,
After the lock hole constituent portion was accommodated and held in the concave portion, the outer peripheral surface of the lock hole constituent portion and the inner peripheral surface of the concave portion opposed to the outer peripheral surface in the radial direction were joined by diffusion bonding.

As a more preferable aspect, the concave portion is formed in a rectangular groove shape extending radially outward from a hole edge of the insertion hole,
The lock hole component is formed in a rectangular shape following the shape of the recess,
After the lock hole constituting portion is accommodated and held in the recess, the both side surfaces of the drive rotating body in the circumferential direction of the lock hole constituting portion and the inner surfaces facing the circumferential direction of the drive rotating body of the recessed portion are diffused. Joined by joining.

  DESCRIPTION OF SYMBOLS 1 ... Sprocket (drive rotary body), 1c ... Insertion hole, 2 ... Camshaft, 3 ... Phase change mechanism, 4 ... 1st hydraulic circuit, 5 ... Position holding mechanism, 6 ... 2nd hydraulic circuit, 7 ... Housing, 7a DESCRIPTION OF SYMBOLS ... Housing main body 9 ... Vane rotor (following rotating body), 10a-10d ... Shoe, 11 ... Delay angle hydraulic chamber, 11a ... 1st communicating hole, 12 ... Advance hydraulic chamber, 12a ... 2nd communicating hole, 15 ... Rotor 15e, 15f ... large diameter part, 16a-16c ... vane, 18 ... retard oil passage, 19 ... advance oil passage, 23 ... fixing groove (recess), 23a ... inner peripheral surface, 24 ... first lock hole 25 ... 2nd lock hole, 26 ... 1st lock pin (lock member), 26b ... tip part, 27 ... 2nd lock pin (lock member) 27b ... tip part, 28 ... lock hole structure part, 28a ... outer peripheral surface 28b ... inner peripheral surface, 29, 30 ... first and second springs (biasing members), 31a, 31b ... first and second pin receiving holes, 43, 44 ... first and second fixing grooves, 43a, 43b, 44a, 44b ... Opposing inner side surfaces, 45, 46 ... first and second lock hole constituent parts, 45a, 45b, 46a, 46b ... both side surfaces

Claims (15)

A driving rotary body formed of a sintered metal to which the rotational force from the crankshaft is transmitted and having a working chamber inside;
A rotor fixed to the camshaft and a vane rotor provided on the outer periphery of the rotor and having a vane that divides the working chamber into a plurality of parts;
A pin receiving hole formed in the vane rotor along the rotational axis direction of the camshaft;
A lock member slidably disposed in the pin accommodation hole;
A recessed portion provided on an inner surface of the driving rotating body facing the working chamber;
The drive rotator has a lock hole that is housed in the recess and into which the tip of the lock member can be engaged when the vane rotor rotates relative to the drive rotator at a predetermined angular position. A lock hole component formed of sintered metal having higher hardness,
With
An internal combustion engine characterized in that the sintered metal material of the drive rotor and the sintered metal material of the lock hole component are mixed and joined in a state where the lock hole component is accommodated in the recess. Engine valve timing control device. The valve timing control apparatus for an internal combustion engine according to claim 1,
The valve timing control device for an internal combustion engine, characterized in that the joining by mixing the sintered metal material of the drive rotating body and the sintered metal material of the lock component is diffusion bonding. The valve timing control apparatus for an internal combustion engine according to claim 1,
The drive rotating body has an insertion hole into which a part of the rotor is inserted, and the concave portion is formed at a hole edge on the inner surface side of the insertion hole. Valve timing control device. The valve timing control apparatus for an internal combustion engine according to claim 3,
The valve timing control device for an internal combustion engine, wherein the lock hole constituting portion housed in the recess has an inner peripheral surface formed in an arc shape along the inner peripheral surface of the insertion hole. The valve timing control apparatus for an internal combustion engine according to claim 3,
The valve timing control device for an internal combustion engine, wherein the recess is formed in an annular groove shape along the entire hole edge of the insertion hole. In the internal combustion engine valve timing control device according to claim 5,
The valve timing control device for an internal combustion engine, wherein the lock hole component is formed in an annular shape following the shape of the recess. The valve timing control apparatus for an internal combustion engine according to claim 6,
The recess is formed in an annular groove shape along the entire hole edge of the insertion hole,
The lock hole component is formed in an annular shape following the shape of the recess,
In a state where the lock hole component is housed and held in the recess, the outer peripheral surface of the lock hole component and the inner peripheral surface of the recess opposed to the outer periphery from the radial direction are in close contact with each other. A valve timing control device for an internal combustion engine. The valve timing control apparatus for an internal combustion engine according to claim 3,
The valve timing control device for an internal combustion engine, wherein the recess is formed in a rectangular groove shape extending radially outward from a hole edge of the insertion hole. The valve timing control device for an internal combustion engine according to claim 8,
The lock hole constituting portion is formed in a rectangular shape following the shape of the recess, and both side surfaces of the drive rotator in the circumferential direction are in close contact with the inner surfaces of the recess in the circumferential direction of the drive rotator. An internal combustion engine valve timing control device. The valve timing control apparatus for an internal combustion engine according to claim 3,
The recess is formed in a fan groove shape extending in the circumferential direction along a hole edge of the insertion hole, and the lock hole constituting portion is formed in a fan shape following the shape of the recess, and the drive A valve timing control device for an internal combustion engine, characterized in that both side surfaces in the circumferential direction of the rotating body are in close contact with opposite inner surfaces in the circumferential direction of the drive rotating body of the recess. A driving rotary body formed of a sintered metal to which the rotational force from the crankshaft is transmitted and having a working chamber inside;
A rotor fixed to the camshaft; a vane provided on an outer periphery of the rotor to divide the working chamber into a plurality of parts; and a pin accommodation hole formed in the rotor or the vane along a rotation axis direction of the rotor. A vane rotor having,
A lock member slidably disposed in the pin accommodation hole;
A recessed portion provided on an inner surface of the driving rotating body facing the working chamber;
A lock hole component formed by a sintered metal that is housed in the recess and has a lock hole into which the tip of the lock member can be engaged, and is harder than the drive rotor;
A method for manufacturing a valve timing control device for an internal combustion engine comprising:
The lock hole component is accommodated in the recess and held in the recess,
Thereafter, the valve of the internal combustion engine, wherein the outer surface of the lock hole component and the inner surface of the recess in contact with the outer surface are joined by diffusion bonding while the lock hole component is housed and held in the recess. A method for manufacturing a timing control device. In the manufacturing method of the valve timing control device of the internal-combustion engine according to claim 11,
The drive rotating body has an insertion hole into which a part of the rotor is inserted, and the concave portion is formed at a hole edge on the inner surface side of the insertion hole. Manufacturing method of valve timing control device. In the manufacturing method of the valve timing control device of the internal-combustion engine according to claim 12,
The inner surface of the lock hole constituting part is formed in an arc shape along the inner peripheral surface of the insertion hole, and then the lock hole constituting part is accommodated and held in the recess, and in this accommodated and held state by diffusion bonding A method for manufacturing a valve timing control device for an internal combustion engine, wherein the lock component is joined in the recess. In the manufacturing method of the valve timing control device of the internal-combustion engine according to claim 12,
The recess is formed in an annular groove shape along the entire hole edge of the insertion hole,
The lock hole component is formed in an annular shape following the shape of the recess,
After the lock hole constituent portion is accommodated and held in the recess, the outer peripheral surface of the lock hole constituent portion and the inner peripheral surface of the concave portion facing the outer peripheral surface from the radial direction are joined by diffusion bonding. A method for manufacturing a valve timing control device for an internal combustion engine. In the manufacturing method of the valve timing control device of the internal-combustion engine according to claim 12,
The recess is formed in a rectangular groove shape extending radially outward from a hole edge of the insertion hole,
The lock hole component is formed in a rectangular shape following the shape of the recess,
After the lock hole constituting portion is accommodated and held in the recess, the both side surfaces of the drive rotating body in the circumferential direction of the lock hole constituting portion and the inner surfaces facing the circumferential direction of the drive rotating body of the recessed portion are diffused. A method for manufacturing a valve timing control device for an internal combustion engine, characterized by being joined by joining.

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