JP2013036400A - Valve timing control device for internal combustion engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a valve timing control device for an internal combustion engine capable of reducing the overall device length dimension in an axial direction even when a coil capacity is increased by increasing the winding number of a coil.SOLUTION: In an electric motor 12, a housing 5 houses therein a core rotor 17 and an electromagnetic coil 18, a commutator 21 is provided at a motor shaft 13 and electrically connected to the electromagnetic coil, first and second brushes 25a, 25b are provided contactably with the commutator, one coil wire 18a of the electromagnetic coil is wound wide in a radial direction, and the other coil wire 18b is accommodated in an annular recess 5d of a partition wall 5b from the axial direction. Accordingly, the enlargement of the overall device length in the axial direction is sufficiently reduced even when the amount of winding of the coil is increased.

Description

  The present invention relates to a valve timing control device for an internal combustion engine that controls the opening / closing timing of intake valves and exhaust valves that are engine valves of the internal combustion engine.

  Recently, a valve timing control device that controls the valve timing of intake valves and exhaust valves by converting the relative rotational phase of the crankshaft and camshaft by transmitting the rotational force of the electric motor to the camshaft via a speed reduction mechanism. Is provided.

  For example, in the valve timing control device described in Patent Document 1 below, a DC motor with a brush is adopted as an electric motor, and power is supplied to the electric motor by using a slip ring and a brush. The rotational force is transmitted to the speed reduction mechanism.

  And the said electric motor and the speed-reduction mechanism are integrally arrange | positioned in the adjacent state from the axial direction inside the housing structural body.

  However, the speed reduction mechanism always requires lubrication oil to lubricate each component, whereas the electric motor supplies lubrication oil because an energization failure occurs when the lubrication oil adheres to an electrical component. There is nothing. Therefore, in order to integrally arrange these in an adjacent state, a partition wall is provided between the speed reduction mechanism and the electric motor, and a relative rotation portion between the motor shaft of the electric motor and the partition wall is provided. An oil seal is provided.

JP 2010-255543 A

  By the way, in the valve timing control device described in the above publication, the coil is wound around the rotor of the electric motor. However, in order to secure a large generated torque of the electric motor, the number of turns of the coil wire is set. This has to be increased, which leads to an increase in the entire coil in the axial direction, that is, an increase in the volume of the coil. Then, in order to prevent interference with a coil, the position of the said partition wall and an oil seal must be shifted to an axial direction, As a result, an apparatus becomes long in an axial direction and will be forced to enlarge.

  An object of the present invention is to provide a valve timing control device for an internal combustion engine that can suppress the axial length of the entire device even when the number of turns of the coil is increased and the coil is extended in the axial direction.

  According to the first aspect of the present invention, in particular, an electric motor for changing valve timing is formed on a rotor made of a magnetic material fixed to an intermediate rotating body and provided with a plurality of slots in the circumferential direction. A coil wound through a slot, a permanent magnet having a plurality of magnetic poles arranged along the circumference of the electric motor housing chamber of the housing component, and provided in the intermediate rotating body, the coil A commutator that is electrically connected to the housing structure, a switching brush provided in contact with the commutator, and provided between the housing structure and an external device. A power feeding mechanism for supplying current to the coil via the switching brush, and the coil is annular in a portion located on the partition wall side in the axial direction. Disposed portion, portion opposite to the partition wall is characterized in that it is wound from the inner circumferential side of the annular recess.

  According to the present invention, even if the axial length (volume) of the coil is increased, the axial length of the entire apparatus can be suppressed.

It is a principal part expanded sectional view of one Embodiment of the valve timing control apparatus which concerns on this invention. It is a longitudinal section showing one embodiment of a valve timing control device concerning the present invention. It is a disassembled perspective view which shows the main structural members in this embodiment. It is the sectional view on the AA line of FIG. FIG. 3 is a sectional view taken along line B-B in FIG. 2. It is CC sectional view taken on the line of FIG. FIG. 3 is a view taken in the direction of arrow D in FIG. 2. It is a side view of a valve timing control device.

  DESCRIPTION OF EMBODIMENTS Hereinafter, an embodiment of a valve timing control device for an internal combustion engine according to the present invention will be described with reference to the drawings. In this embodiment, the present invention is applied to the valve operating device on the intake side of the internal combustion engine, but it can also be similarly applied to the valve operating device on the exhaust side.

  As shown in FIGS. 2 and 3, this valve timing control device is rotatable on a timing sprocket 1 that is a drive rotating body that is rotationally driven by a crankshaft of an internal combustion engine, and on a cylinder head via a bearing not shown. A camshaft 2 that is supported and rotated by the rotational force transmitted from the timing sprocket 1, a cover member 3 fixed to a chain cover (not shown) disposed in front of the timing sprocket 1, the timing sprocket 1 and the cam And a phase change mechanism 4 that is disposed between the shafts 2 and changes the relative rotational phases of both 1 and 2 in accordance with the engine operating state.

  The timing sprocket 1 is formed integrally with an iron-based metal in an annular shape, and the inner peripheral surface is integrally provided on the outer periphery of the sprocket body 1a with a stepped diameter, and is wound outside the drawing. The gear gear 1b that receives the rotational force from the crankshaft via the timing chain and the annular member 19 that is integrally provided on the front end side of the sprocket body 1a.

  The timing sprocket 1 includes a large-diameter ball bearing 43 as a bearing interposed between a sprocket body 1a and a driven member 9 described later provided at the front end of the camshaft 2. The large-diameter ball bearing 43 supports the timing sprocket 1 and the camshaft 2 so as to be relatively rotatable.

  As shown in FIGS. 1 to 3, the large-diameter ball bearing 43 includes an outer ring 43a, an inner ring 43b, and a ball 43c interposed between the wheels 43a and 43b. In the large-diameter ball bearing 43, the outer ring 43a is fixed to the inner peripheral side of the sprocket body 1a, whereas the inner ring 43b is fixed to the outer peripheral side of the driven member 9 described later.

  In the sprocket body 1a, an annular groove-shaped outer ring fixing portion 60 opened to the camshaft 2 side is cut out on the inner peripheral side.

  As shown in FIG. 1, the outer ring fixing portion 60 is formed in a stepped diameter shape and has an annular inner peripheral surface 60 a extending in the camshaft axial direction, and the opposite side of the inner peripheral surface 60 a from the opening. And a first fixed step surface 60b formed along the radial direction. An outer ring 43a of the large-diameter ball bearing 43 is press-fitted from the axial direction into the inner peripheral surface 60a, and an axial inner end face 43d of the outer ring 43a is press-fitted into the first fixed step surface 60b. The outer ring 43a is positioned so as to contact one side in the axial direction.

  As shown in FIGS. 1 to 3, the annular member 19 is integrally formed on the outer peripheral side of the front end portion of the sprocket body 1 a and is formed in a cylindrical shape extending in the direction of the electric motor 12 of the phase changing mechanism 4. In addition, wave-shaped internal teeth 19a are formed on the inner periphery. A plurality of the internal teeth 19a are continuously formed at equal intervals in the circumferential direction. An annular female screw forming portion 6 that is integral with a housing 5 (described later) of the electric motor 12 is disposed on the front end side of the annular member 19.

  An annular holding plate 61 is disposed at the rear end of the sprocket body 1a opposite to the annular member 19. The holding plate 61 is integrally formed of a relatively thin metal plate, and as shown in FIG. 2, the outer diameter is set to be substantially the same as the outer diameter of the sprocket body 1a, and the inner diameter is the large-diameter ball. The diameter of the bearing 43 is set near the center in the radial direction.

  Accordingly, the inner peripheral portion 61a of the holding plate 61 is disposed so as to cover the outer end surface 43e in the axial direction of the outer ring 43a with a certain gap. Further, a stopper convex portion 61b protruding inward in the radial direction, that is, in the central axis direction is integrally provided at a predetermined position on the inner peripheral edge of the inner peripheral portion 61a.

  As shown in FIGS. 3 and 5, the stopper convex portion 61b is formed in a substantially fan shape, and the tip edge 61c is formed in an arc shape along an arc-shaped inner peripheral surface of a stopper groove 2b described later. Further, six bolt insertion holes 61d through which the respective bolts 7 are inserted are formed in the outer peripheral portion of the holding plate 61 at equal intervals in the circumferential direction.

  Further, an annular spacer 62 is interposed between the inner surface of the holding plate 61 and the outer end surface 43e of the outer ring 43a of the large-diameter ball bearing 43 facing the inner surface. The spacer 62 applies a slight pressing force from the inner surface of the holding plate 61 to the outer end surface 43e of the outer ring 43a when the holding plate 61 is fastened and fixed together by the bolts 7. The thickness is set to such a thickness that a minute gap within the allowable range of axial movement of the outer ring 43a is formed between the outer end surface 43e of the outer ring 43a and the holding plate 61.

  Six bolt insertion holes 1c and 61d are formed through the outer peripheral portions of the sprocket body 1a (annular member 19) and the holding plate 61 at substantially equal intervals in the circumferential direction. The female screw forming portion 6 has six female screw holes 6a formed at positions corresponding to the bolt insertion holes 1c and 61d. The six bolts 7 inserted through these female screws 6a and 6d have the three members 61, 1, 6 (housing 5) is fastened together.

  The sprocket body 1a and the annular member 19 are configured as a casing of a speed reduction mechanism 8 to be described later, and a housing structure is configured by the casing and a housing 5 to be described later.

  The sprocket body 1a, the annular member 19, the holding plate 61, and the female thread forming portion 6 are set to have substantially the same outer diameter.

  The cover member 3 is integrally formed in a cup shape with an aluminum alloy material, and a bulging portion 3a formed at the front end portion is provided so as to cover the front end portion of the housing 5, and the bulging portion A cylindrical wall 3b is integrally formed along the axial direction on the outer peripheral side of 3a. As shown in FIGS. 2 and 3, the cylindrical wall 3 b has a holding hole 3 c formed therein, and the inner peripheral surface of the holding hole 3 c is configured as a guide surface of a brush holder 28 described later. ing.

  In addition, as shown in FIG. 2, the cover member 3 has six bolt insertion holes 3e formed through the flange portion 3d formed on the outer periphery, and the bolts outside the figure inserted through the bolt insertion holes 3e. It is fixed to the chain cover.

  As shown in FIG. 2, a large-diameter oil seal 50 as a second seal member is interposed between the inner peripheral surface of the stepped portion on the outer peripheral side of the bulging portion 3 a and the outer peripheral surface of the housing 5. ing. The large-diameter oil seal 50 is formed in a substantially U-shaped cross section, a core metal is embedded in the synthetic rubber base material, and an annular base on the outer peripheral side is the inner periphery of the cover member 3. It is fitted and fixed to a step ring portion 3h provided on the surface.

  The housing 5 is made of a housing main body 5a which is a cylindrical portion formed by pressing a ferrous metal material into a bottomed cylindrical shape, and a non-magnetic material made of a synthetic resin that seals the front end opening of the housing main body 5a. And a sealing plate 11.

  The housing body 5a is provided with a disc-shaped partition wall 5b on the rear end side, and an annular fixing groove for fitting and fixing the outer periphery of the sealing plate 11 is formed on the inner periphery of the front end. Yes.

  As shown in FIGS. 1 and 2, the partition wall 5b has a large-diameter shaft insertion hole 5c through which an eccentric shaft portion 39, which will be described later, is inserted at a substantially central position. The female thread forming portion 6 is formed from the axial direction. An annular recess 5d is formed on the front end surface on the inner side of the female thread forming member 6 of the partition wall 5b. In the annular recess 5d, the inner peripheral surface 5e on the female screw forming portion 6 side is formed in a tapered surface whose diameter is increased with respect to the bottom surface, and the inner inner peripheral surface 5f is formed perpendicular to the bottom surface. Has been.

  The camshaft 2 has two drive cams per cylinder for opening an intake valve (not shown) on the outer periphery, and the flange portion 2a is integrally provided at the front end.

  As shown in FIGS. 1 and 2, the flange portion 2a is set to have an outer diameter slightly larger than an outer diameter of a fixed end portion 9a of a driven member 9 to be described later. The outer peripheral portion of 2e is arranged in contact with the outer end surface in the axial direction of the inner ring 43b of the large-diameter ball bearing 43. Further, the front end face 2e is coupled from the axial direction by the cam bolt 10 in a state where the front end face 2e is in contact with the driven member 9 from the axial direction.

  Further, as shown in FIG. 5, a stopper concave groove 2b into which the stopper convex portion 61b of the holding plate 61 is engaged is formed on the outer periphery of the flange portion 2a along the circumferential direction. The stopper concave groove 2b is formed in a circular arc shape having a predetermined length in the circumferential direction, and both end edges of the stopper convex portion 61b rotated within this length range abut against the circumferential opposite edges 2c and 2d, respectively. Thus, the relative rotational position of the camshaft 2 on the maximum advance angle side or the maximum retard angle side with respect to the timing sprocket 1 is regulated.

  The stopper convex portion 61b is disposed at a position closer to the camshaft 2 than a portion of the holding plate 61 fixed to the outer ring 43a of the large-diameter ball bearing 43 facing the outer side in the axial direction. 9 is in a non-contact state with the fixed end 9a. Therefore, interference between the stopper convex portion 61b and the fixed end portion 9a can be sufficiently suppressed.

  The stopper convex portion 61b and the stopper concave groove 2b constitute a stopper mechanism.

  As shown in FIG. 2, the cam bolt 10 has an annular washer portion 10c disposed on the end surface of the head portion 10a on the shaft portion 10b side, and an outer periphery of the shaft portion 10b from the end portion of the camshaft 2. A male screw portion 10d that is screwed into a female screw portion formed in the inner axial direction is formed.

  The driven member 9 is integrally formed of a ferrous metal material, and as shown in FIG. 2, a disc-shaped fixed end portion 9a formed on the front end side, and an inner peripheral front end surface of the fixed end portion 9a. A cylindrical portion 9b protruding in the axial direction and a cylindrical retainer 41 that is formed integrally with the outer peripheral portion of the fixed end portion 9a and holds a plurality of rollers 48 are formed.

  The fixed end portion 9 a has a rear end surface disposed in contact with a front end surface of the flange portion 2 a of the camshaft 2, and is pressed and fixed to the flange portion 2 a from the axial direction by the axial force of the cam bolt 10.

  As shown in FIG. 2, the cylindrical portion 9b has a through hole 9d through which the shaft portion 10b of the cam bolt 10 is inserted, and a needle bearing 38 on the outer peripheral side.

  1 to 4, the retainer 41 is bent into a substantially L-shaped cross section from the front end of the outer peripheral portion of the fixed end portion 9a, and protrudes in the same direction as the cylindrical portion 9b. It is formed in a shape. The cylindrical tip 41a of the retainer 41 extends in the direction of the partition wall 5b via an annular space 44. In addition, a plurality of substantially rectangular roller holding holes 41b, which are roller holding portions for holding the plurality of rollers 48 in a freely rolling manner, are arranged at substantially equal intervals in the circumferential direction of the tip end portion 41a. Formed in position. The total number of the roller holding holes 41b (rollers 48) is one less than the total number of teeth of the inner teeth 19a of the annular member 19.

  An inner ring fixing portion 63 for fixing the inner ring 43b of the large-diameter ball bearing 43 is formed in a notch between the outer peripheral portion of the fixed end portion 9a and the bottom side coupling portion of the cage 41.

  As shown in FIG. 1, the inner ring fixing portion 63 is formed in a stepped shape facing the outer ring fixing portion 60 in the radial direction, and has an annular outer peripheral surface 63a extending in the camshaft axial direction. The outer peripheral surface 63a is integrally formed opposite to the opening, and includes a second fixed step surface 63b formed along the radial direction. An inner ring 43b of a large-diameter ball bearing 43 is press-fitted from the axial direction to the outer peripheral surface 63a, and an inner end face 43f of the press-fitted inner ring 43b abuts on the second fixed step surface 63b. It is designed to be positioned.

  The phase changing mechanism 4 includes the electric motor 12 that is an actuator disposed on the substantially coaxial front end side of the camshaft 2, and the speed reducing mechanism that reduces the rotational speed of the electric motor 12 and transmits it to the camshaft 2. 8.

  As shown in FIGS. 2 and 3, the electric motor 12 is a brushed DC motor, which is a yoke that rotates integrally with the timing sprocket 1, and the housing 5 is rotatable inside the housing 5. A motor shaft 13 (output shaft) that is an intermediate rotating body provided on the inner surface of the housing 5, a pair of semicircular arc permanent magnets 14 and 15 that are stators fixed to the inner peripheral surface of the housing 5, and the sealing plate 11 A fixed stator 16.

  As shown in FIG. 1, the motor shaft 13 is formed in a stepped cylindrical shape and functions as an armature, and has a large diameter portion on the camshaft 2 side through a stepped portion 13c formed at a substantially central position in the axial direction. 13a and a small diameter portion 13b on the brush holder 28 side. Further, the iron core rotor 17 is fixed to the outer periphery of the large diameter portion 13a, and an eccentric shaft portion 39 is press-fitted and fixed in the large diameter portion 13a from the axial direction, and an eccentric shaft is formed by the inner surface of the step portion 13c. The portion 39 is positioned in the axial direction.

  On the other hand, an annular member 20 is press-fitted and fixed to the outer periphery of the small-diameter portion 13b, and a commutator 21 is press-fitted and fixed to the outer peripheral surface of the annular member 20 from the axial direction. Directional positioning has been made. The outer diameter of the annular member 20 is set to be substantially the same as the outer diameter of the large-diameter portion 13a, and the axial length is set slightly shorter than the small-diameter portion 13b. The annular member 20 and the commutator 21 constitute a commutator unit.

  Since the eccentric shaft portion 39 and the commutator 21 can be positioned in the axial direction by the inner and outer surfaces of the step portion 13c, the assembling work is facilitated and the positioning accuracy is improved.

  The iron core rotor 17 is formed of a magnetic material having a plurality of magnetic poles, and the outer peripheral side is configured as a bobbin having a slot around which the coil wire of the electromagnetic coil 18 is wound. As shown in FIGS. 1 and 2, the bobbin has first and second jaw portions 17 a and 17 b that are bent substantially in an L shape at the front and rear positions in the axial direction.

  The first and second jaw portions 17a and 17b are for positioning the coil windings 18a and 18b of the electromagnetic coil 18 on the inner peripheral side near the motor shaft 13, and the first jaw portion 17a on the commutator 21 side is Further, it is arranged closer to the inner peripheral side than the second jaw portion 17b, that is, is arranged close to the large diameter portion 13a side, and a part of the front end overlaps a part of the commutator 21 from the axial direction. An annular space S is formed between the first jaw 17a and the commutator 21. In other words, a part of the rear end side (folded portion 21a described later) of the commutator 21 enters the inside of the first jaw portion 17a from the axial direction, and the inner periphery of the first jaw portion 17a. An annular space S is formed between the surface and the rear end side of the commutator 21. On the other hand, the outer peripheral part of the second jaw part 17b on the opposite side is fitted into the annular recess 5d of the partition wall 5b.

  Therefore, the electromagnetic coil 18 is wound so that one coil winding 18 a on the commutator 21 side and the other coil winding 18 b on the camshaft 2 side are asymmetrical about the iron core rotor 17.

  That is, one coil winding 18a is wound from a position close to the motor shaft 13 via the first jaw 17a, while the other coil winding 18b is wound on the housing 5 via the second jaw 17b. In the form of being housed in the annular recess 5d of the partition wall 5b, the partition walls 5b are arranged close to each other in the axial direction.

  On the other hand, the commutator 21 is formed in a ring shape by a conductive material, and the coil wire terminal 18c from which the electromagnetic coil 18 is drawn is electrically connected to each segment divided into the same number as the number of poles of the iron core rotor 17. It is connected. That is, the end of the coil wire 18c is sandwiched in the annular space S and electrically connected to the folded portion 21a which is a connecting portion formed on the inner peripheral side.

  And as shown by the black dot pattern of FIG. 1, FIG. 2, the varnish 54 which consists of a resin solvent is apply | coated and filled in each outer surface of the said iron core rotor 17 and the electromagnetic coil 18, and the said annular space S. As shown in FIG.

  The varnish 54 is generally applied as an insulating material to the outer periphery of the coil wire of the electromagnetic coil 18, and is wound in advance on the entire outer peripheral surface of the iron core rotor 17 and on the outer peripheral side of the iron core rotor 17. It is applied to the entire outer surface of the electromagnetic coil 18 and further filled in an annular space S formed between the inner peripheral surface of the bobbin (first jaw portion 17a) and the commutator 21.

  In the annular space S, the terminal 18c of the coil wire is in a state of being pulled with a predetermined tension, and the tip of the terminal 18c is sandwiched between the folded portions 21a of the commutator 21, and is in a connected state. The terminal 18 c of the coil wire and the entire connecting portion at the tip of the terminal 18 c are fixed between the first jaw 17 a and the commutator 21 while being covered with the varnish 54.

  The permanent magnets 14, 15 are formed in a cylindrical shape as a whole and have a plurality of magnetic poles in the circumferential direction, and their axial positions are offset from the fixed position of the iron core rotor 17. ing.

  More specifically, as shown in FIGS. 1 and 2, the permanent magnets 14 and 15 have an axial center P that is a predetermined distance α away from the axial center P1 of the iron core rotor 17. Only in the forward direction, that is, offset to the stator 16 side.

  Further, by this, the front end portions 14a and 15a of the permanent magnets 14 and 15 are arranged so as to overlap with the commutator 21 and first brushes 25a and 25b described later of the stator 16 in the radial direction.

  As shown in FIG. 6, the stator 16 includes a disk-shaped resin plate 22 integrally provided on the inner peripheral side of the sealing plate 11 and a pair of resin plates 22 provided on the inner side of the resin plate 22. Resin holders 23a and 23b and the resin holders 23a and 23b are slidably accommodated in the radial direction, and the distal end surfaces thereof are outer peripheral surfaces of the commutator 21 by the spring force of the coil springs 24a and 24b. A pair of first brushes 25a and 25b, which are switching brushes (commutators) that elastically contact with each other in the radial direction, and inner and outer doubles that are embedded and fixed to the front end surfaces of the resin holders 23a and 23b with the respective outer end surfaces exposed. Annular slip rings 26a, 26b, pigtail harnesses 27a, 27b electrically connecting the first brushes 25a, 25b and the slip rings 26a, 26b, It is configured as al main. The slip rings 26a, 26b and second brushes 30a, 30b described later are configured as a power feeding mechanism, and the first brushes 25a, 25b, the commutator 21, the pigtail harnesses 27a, 27b, and the like are configured as energization switching means. ing.

  The sealing plate 11 is positioned and fixed by caulking to a concave step formed on the inner periphery of the front end of the housing 5. Further, a shaft insertion hole 11a through which one end of the motor shaft 13 and the like are inserted is formed at the center position.

  A brush holder 28 which is a power supply brush unit integrally molded with a synthetic resin material is fixed to the bulging portion 3a.

  As shown in FIGS. 2, 3 and 8, the brush holder 28 is formed in a substantially L shape in a side view, and has a substantially cylindrical brush holding portion 28a inserted into the holding hole 3c. A connector portion 28b at the upper end of the brush holding portion 28a; a pair of bracket portions 28c, 28c that are integrally projected on both sides of the brush holding portion 28a and fixed to the bulging portion 3a; and the brush The main body is mainly composed of a pair of terminal pieces 31 and 31 which are mostly embedded in the holding body 28.

  The pair of terminal pieces 31 and 31 are formed in a parallel and crank shape along the vertical direction, and the terminals 31a and 31a on one side (lower end side) are arranged in an exposed state on the bottom side of the brush holding portion 28a. On the other hand, the terminals (31b, 31b) on the other side (upper end side) protrude from the female fitting groove 28d of the connector portion 28b. The other terminals 31a and 31b are electrically connected to a battery power source via male terminals (not shown).

  The brush holding portion 28a extends substantially in the horizontal direction (axial direction), and sleeve-like sliding portions 29a and 29b are fixed in cylindrical through holes formed at the upper and lower positions inside the brush holding portion 28a. The second brushes 30a and 30b whose tip surfaces abut on the slip rings 26a and 26b from the axial direction are held in the sliding portions 29a and 29b so as to be slidable in the axial direction.

  Each of the second brushes 30a and 30b is formed in a substantially rectangular shape and is a second biasing member that is elastically mounted between the one side terminals 31a and 31a facing the bottom side of each through hole. The coil springs 32a and 32b are urged toward the slip rings 26a and 26b by the spring force of the coil springs 32a and 32b, respectively.

  In addition, a pair of flexible pigtail harnesses 33a and 33b are fixed by welding between the rear end portions of the second brushes 30a and 30b and the one-side terminals 31a and 31a. Connected to. The pigtail harnesses 33a and 33b have a length so that the second brushes 30a and 30b do not fall off the sliding portions 29a and 29b when the second brushes 30a and 30b are advanced to the maximum by the coil springs 32a and 32b. The length is set to regulate the maximum sliding position.

  An annular seal member 34 is fitted and held in an annular fitting groove formed on the base side outer periphery of the brush holding portion 28a, and the brush holding portion 28a is inserted into the holding hole 3c. When this occurs, the seal ring 34 elastically contacts the tip surface of the cylindrical wall 3b to seal the inside of the brush holding portion 28a.

  In the connector portion 28b, the other side terminals 31b and 31b facing the fitting groove 28d in which the male terminal (not shown) is inserted into the upper end portion are electrically connected to the control unit (not shown) via the male terminal. It is connected to the.

  The bracket portions 28c, 28c are formed in a substantially triangular shape, and bolt insertion holes 28e, 28e are formed through both sides. The bolt insertion holes 28e, 28e are respectively inserted with bolts 36, 36 which are screwed into a pair of female screw holes 3f, 3f formed in the bulging portion 3a, and are inserted into the bolt insertion holes 28e, 28e via the bracket portions 28c, 28c. The brush holder 28 is fixed to the bulging portion 3a.

  The motor shaft 13 and the eccentric shaft portion 39 are provided on the outer peripheral surface of the small diameter ball bearing 37 provided on the outer peripheral surface of the shaft portion 10 b on the head 10 a side of the cam bolt 10 and the cylindrical portion 9 b of the driven member 9. And the needle bearing 38 disposed on the axial side of the small-diameter ball bearing 37 is rotatably supported. The small diameter ball bearing 37 and the needle bearing 38 constitute a bearing mechanism.

  The needle bearing 38 includes a cylindrical retainer 38a press-fitted into the inner peripheral surface of the eccentric shaft portion 39, and needle rollers 38b that are a plurality of rolling elements rotatably held in the retainer 38a. ing. The needle roller 38 b rolls on the outer peripheral surface of the cylindrical portion 9 b of the driven member 9.

  The small-diameter ball bearing 37 has an inner ring fixed between the front end edge of the cylindrical portion 9 b of the driven member 9 and a washer 10 c of the cam bolt 10, while an outer ring is formed on the inner periphery of the motor shaft 13. The positioning is supported from the axial direction between the stepped portion and the snap ring 45 which is a retaining ring.

  Further, between the outer peripheral surface of the motor shaft 13 (eccentric shaft portion 39) and the inner peripheral surface of the shaft portion insertion hole 5c of the partition wall 5b, lubricating oil from the inside of the speed reduction mechanism 8 into the electric motor 12 is obtained. A small-diameter oil seal 46, which is a small-diameter seal member that prevents the leakage, is provided. The small-diameter oil seal 46 separates the electric motor 12 and the speed reduction mechanism 8, and the inner peripheral portion elastically contacts the outer peripheral surface of the motor shaft 13, thereby preventing the motor shaft 13 from rotating. On the other hand, frictional resistance is given.

  The control unit detects the current engine operating state based on information signals from various sensors such as a crank angle sensor, an air flow meter, a water temperature sensor, and an accelerator opening sensor (not shown), and performs engine control. The electromagnetic coil 18 is energized to control the rotation of the motor shaft 13 and the relative rotation phase of the camshaft 2 with respect to the timing sprocket 1 is controlled via the speed reduction mechanism 8.

  As shown in FIGS. 2 and 3, the speed reduction mechanism 8 includes the eccentric shaft portion 39 that performs eccentric rotational movement, a medium-diameter ball bearing 47 provided on the outer periphery of the eccentric shaft portion 39, and the medium-diameter ball. The roller 48 provided on the outer periphery of the bearing 47; the retainer 41 that allows the roller 48 to move in the radial direction while retaining the roller 48 in the rolling direction; and the driven member 9 that is integral with the retainer 41; Is mainly composed of

  The eccentric shaft portion 39 is formed in a cylindrical shape with a step diameter, and the small diameter portion 39a on the front end side is press-fitted and fixed to the inner peripheral surface of the large diameter portion 13a of the motor shaft 13 described above. The axis Y of the cam surface formed on the outer peripheral surface of the large-diameter portion 39b is slightly eccentric in the radial direction from the axis X of the motor shaft 13. The medium-diameter ball bearing 47 and the roller 48 are configured as planetary meshing portions.

  The medium-diameter ball bearing 47 is disposed so as to be substantially overlapped at the radial position of the needle bearing 38, and includes an inner ring 47a, an outer ring 47b, and a ball 47c interposed between the two wheels 47a and 47b. It is configured. The inner ring 47a is press-fitted and fixed to the outer peripheral surface of the eccentric shaft portion 39, whereas the outer ring 47b is in a free state without being fixed in the axial direction. That is, in the outer ring 47b, one end surface on the electric motor 12 side in the axial direction is not in contact with any part, and the other end surface 47d in the axial direction is minute between the inner side surface of the cage 41 facing the outer ring 47b. The first gap C is formed and is in a free state. Further, the outer peripheral surface of the outer ring 47b is in contact with the outer peripheral surface of each roller 48 so as to be freely rotatable, and an annular second gap C1 is formed on the outer peripheral side of the outer ring 47b. Due to the second gap C1, the entire medium-diameter ball bearing 47 can move in the radial direction along with the eccentric rotation of the eccentric shaft portion 39, that is, can move eccentrically.

  The rollers 48 are fitted in the inner teeth 19a of the annular member 19 while moving in the radial direction along with the eccentric movement of the medium-diameter ball bearing 47, and are surrounded by both side edges of the roller holding holes 41b of the cage 41. It is designed to swing in the radial direction while being guided in the direction.

  Lubricating oil is supplied into the speed reduction mechanism 8 by lubricating oil supply means. The lubricating oil supply means is formed inside the bearing of the cylinder head, and includes an oil supply passage through which lubricating oil is supplied from a main oil gallery (not shown), and the inside of the camshaft 2 as shown in FIG. An oil supply hole 51 that is formed in the axial direction and communicates with the oil supply passage through a groove groove, and is formed so as to penetrate in the inner axial direction of the driven member 9, and one end opens to the oil supply hole 51, The other end of the small-diameter oil hole 52 opened in the vicinity of the needle bearing 38 and the medium-diameter ball bearing 47, and the three large-diameter oil discharge holes outside the figure formed in the driven member 9 in the same manner. It is configured.

  By this lubricating oil supply means, the lubricating oil is supplied and stays in the space portion 44, and from here, the lubricating oil is sufficiently supplied to movable parts such as the medium-diameter ball bearing 47 and each roller 48. . The lubricating oil staying in the space 44 is prevented from leaking into the housing 5 by the small diameter oil seal 46.

  As shown in FIG. 2, a cap 53 having a substantially U-shaped cross section for closing the space on the cam bolt 10 side is press-fitted and fixed inside the front end of the motor shaft 13.

  Hereinafter, the operation of the present embodiment will be described. First, when the crankshaft of the engine is rotationally driven, the timing sprocket 1 is rotated via the timing chain 42, and the rotational force is transmitted via the annular member 19 and the female screw forming portion 6. The housing 5, that is, the electric motor 12, rotates synchronously. On the other hand, the rotational force of the annular member 19 is transmitted from each roller 48 to the camshaft 2 via the cage 41 and the driven member 9. As a result, the cam of the camshaft 2 opens and closes the intake valve.

  When a predetermined engine is operated after the engine is started, the electric motor 12 is connected to the control unit from the terminal pieces 31 and 31 through the pigtail harnesses 32a and 32b, the second brushes 30a and 30b, the slip rings 26a and 26b, and the like. The electromagnetic coil 17 is energized. As a result, the motor shaft 13 is rotationally driven, and the rotational force that is reduced in speed to the camshaft 2 is transmitted via the speed reduction mechanism 8.

  That is, when the eccentric shaft portion 39 rotates eccentrically with the rotation of the motor shaft 13, the rollers 48 are guided in the radial direction by the roller holding holes 41 b of the retainer 41 for each rotation of the motor shaft 13. It moves while rolling over one inner tooth 19a of 19 and moving to another adjacent inner tooth 19a, and repeatedly contacts this in the circumferential direction. By the rolling contact of each roller 48, the rotation of the motor shaft 13 is decelerated, and the rotational force is transmitted to the driven member 9. The reduction ratio at this time can be arbitrarily set according to the number of rollers 48 or the like.

  As a result, the camshaft 2 rotates relative to the timing sprocket 1 in the forward and reverse directions and the relative rotational phase is converted, so that the opening / closing timing of the intake valve is controlled to be advanced or retarded.

  And, the maximum position restriction (angular position restriction) of forward and reverse relative rotation of the camshaft 2 with respect to the timing sprocket 1 is that each side surface of the stopper convex portion 61b is one of the opposing surfaces 2c and 2d of the stopper concave groove 2b. This is done by contacting one side.

  Specifically, when the driven member 9 rotates in the same direction as the rotation direction of the timing sprocket 1 as the eccentric shaft portion 39 rotates eccentrically, one side surface of the stopper convex portion 61b becomes the stopper concave groove 2b. Further, the rotation in the same direction is restricted by coming into contact with the opposite surface 1c on one side. As a result, the relative rotation phase of the camshaft 2 with respect to the timing sprocket 1 is changed to the maximum on the advance side.

  On the other hand, when the driven member 9 rotates in the direction opposite to the rotation direction of the timing sprocket 1, the other side surface of the stopper convex portion 61b abuts against the opposite surface 2d on the other side of the stopper concave groove 2b and the same direction beyond that. Rotation is regulated. As a result, the relative rotation phase of the camshaft 2 with respect to the timing sprocket 1 is changed to the maximum on the retard side.

  As a result, the opening / closing timing of the intake valve is converted to the maximum on the advance side or the retard side, and the fuel efficiency and output of the engine can be improved.

  In this embodiment, as described above, one coil winding 18a of the electromagnetic coil 18 is wound from the inner peripheral side sufficiently close to the commutator 21 side (axial direction) via the first jaw portion 17a. Since it can be turned, the amount of protrusion in the axial direction can be suppressed even if the winding amount of the coil winding 18a is increased. Further, since the other coil winding 18b can be disposed in the annular recess 5d of the housing partition wall 5b in the accommodated state from the axial direction, even if the winding amount of the coil winding 18b is increased by this arrangement configuration, Since it can absorb in the annular recess 5d, the axial length of the apparatus can be made as small as possible.

  As described above, the winding amount of both the coil windings 18a and 18b can be increased to ensure a large generated torque of the electric motor 12, and even if the winding amount is increased, the winding amount is increased in the radial direction and the winding amount is increased. Absorption into the annular recess 5d makes it possible to shorten the overall axial length of the apparatus as much as possible.

  In addition, the small-diameter oil seal 46 is not positioned at a suitable axial position, but is arranged between the inner peripheral surface of the shaft portion insertion hole 5c of the partition wall 5b and the outer peripheral surface of the eccentric shaft portion 39 in the axial direction. Therefore, the axial length of the apparatus can be suppressed in this respect as well.

  As a result, the length of the apparatus in the axial direction is sufficiently suppressed, so that the mounting property to the internal combustion engine is improved.

  Further, the annular recess 5d formed in the partition wall 5b has an outer peripheral side inner peripheral surface 5e formed in a diameter-expanded taper shape, so that the thickness of the female screw forming portion 6 is sufficiently secured and high rigidity. Can be obtained. Therefore, it is possible to obtain a high tightening torque at the female screw hole 6a of each bolt 7.

  Furthermore, in the present embodiment, as described above, the varnish 54 is applied to the outer peripheral surfaces of the iron core rotor 17 and the electromagnetic coil 18, and the varnish 54 is filled in the annular space S. The mass of the entire rotor core including the iron core rotor 17, the electromagnetic coil 18, the motor shaft 13, the annular member 20, and the commutator 20 is increased by the weight of the varnish 544. For this reason, since the moment of inertia at the time of rotation of the rotor core increases, the influence of the alternating torque transmitted from the camshaft 2 to the speed reduction mechanism 8 on the rotor core such as the iron core rotor 17 and the electromagnetic coil 18 is affected. It can suppress, and the fluctuation | variation of the rotation direction of this rotor core can be suppressed.

  In addition, by sufficiently suppressing the influence of vibration on the electromagnetic coil 18, it is possible to suppress a decrease in the control performance of the electric motor 12.

  Moreover, the annular space S between the commutator 21 and the first jaw portion 17a is also filled with the varnish 54, and the connection portion (folding portion 21a) between the terminal 18c of the coil wire and the commutator 21 at the tip of the terminal 18c. Is fixed and held by the varnish 54, even if vibration due to disturbance such as an alternating torque of the camshaft 2 is transmitted here, the occurrence of disconnection at the coil wire terminal 18 c and the connecting portion is sufficient. And vibration resistance is improved.

  Further, the vibration resistance of the coil wire terminal 18c generally depends on the tension of the coil wire terminal 18c, but in the present embodiment, the vibration resistance is obtained not by tension but by the holding force of the varnish 54 as described above. Thus, the degree of freedom in layout between the commutator 21 and the iron core rotor 17 is improved.

  That is, as a normal assembly procedure for components such as the commutator 21, first, the commutator 21 is press-fitted and fixed to the outer periphery of the small diameter portion 13b of the motor shaft 13 via the annular member 20, and then the coil wires 18a and 18b. Is wound around the outer periphery of the iron core rotor 17 and tension is applied to the end 18c of the coil wire in this state to improve vibration resistance. However, in this case, there must be sufficient space in the fixed portion of the commutator 21. For example, since sufficient tension cannot be applied to the terminal 18c of the coil wire, the amount of press-fitting of the commutator 21 into the motor shaft 13 must be limited.

  However, in this embodiment, since the vibration resistance can be improved by the holding force of the varnish 54 instead of the tension of the coil wire terminal 18c, the coil wires 18a and 18b are wound around the iron core rotor 17 before this. The tip of the coil wire terminal 18c can be connected to the commutator 21 via the folded portion 21a, and then the commutator 21 can be press-fitted and fixed to the small diameter portion 13b via the annular member 20. Therefore, it is not necessary to secure an extra space between the connecting portion that is the folded portion 21a of the commutator 21 and the coil winding 18a. That is, as described above, since the annular space S between the commutator 21 and the coil winding 18a can be made sufficiently small in the axial direction, the axial length of the apparatus can be made as small as possible. it can. As a result, the mountability of the apparatus to the internal combustion engine is improved.

  Moreover, since the wire diameter of the coil can be reduced as much as possible by suppressing the disconnection of the coil wire terminal 18c and the connecting portion, the number of coil turns to the iron core rotor 17 can be increased. . Thereby, the output torque of the electric motor 12 can be improved with a small energization amount.

  Further, in the present embodiment, as described above, since the axial center P of the permanent magnets 14 and 15 is offset forward from the axial center P1 of the iron core rotor 17, the permanent magnets 14 and 15 As shown by the arrow in FIG. 1, the iron core rotor 17 is attracted forward (leftward in the figure) by the magnetic force generated between the iron core rotor 17 and the iron core rotor 17. The shaft part 39 is always attracted in the direction of the arrow. That is, since the magnetic force of the permanent magnets 14 and 15 and the magnetic force of the iron core rotor 17 are the largest at the respective axial centers P and P1, the attractive force with respect to the iron core rotor 17 in the center P direction of the permanent magnets 14 and 15 is increased. Larger and strongly attracted in the direction of the arrow.

  Accordingly, in addition to the small-diameter ball bearing 37 and the needle bearing 38, the medium-diameter ball bearing 47 is also attracted in the arrow direction.

  For this reason, generation | occurrence | production of the noise accompanying the slight vibration of the said ball bearings 37 and 47 and the needle bearing 38 by the alternating torque which generate | occur | produces in the said camshaft 2 due to the spring force of a valve spring, etc. is suppressed. Is possible.

  Further, by offsetting the positions of the permanent magnets 14 and 15 in the axial direction, the front end portions 14a and 15a can be overlapped with the first brushes 25a and 25b and the commutator 21, so that the axial direction of the apparatus can be increased. It becomes possible to make the length as small as possible.

  Further, since the lubricating oil is forcibly supplied into the speed reduction mechanism 8 from the oil supply hole 51 and the oil hole 52, the lubricity of each part of the speed reduction mechanism 8 is improved and the internal teeth 19a and the rollers 48 are improved. Lubricating oil is supplied to the needle bearing 38 and the medium-diameter ball bearing 47 to improve the lubricity between each needle roller 38b and each ball, and the speed reduction mechanism 8 always performs a smooth phase conversion. Needless to say, since this lubricating oil exhibits a buffering function, it is possible to more effectively suppress the occurrence of hitting sound at each part.

  In particular, during the operation of the engine, since the lubricating oil pumped from the oil pump is constantly supplied and immersed in the space 44 through the lubricating oil supply means, each rolling element such as the ball bearing is provided. And the occurrence of oil film breakage at the sliding portion can be suppressed. Thereby, the initial driving load of the electric motor 12 can be sufficiently reduced, and the control response of the valve timing can be improved and the energy consumption can be reduced.

  In addition, the housing 5 can be integrated with the speed reduction mechanism 8 and the electric motor 12, and can also be integrated with the timing sprocket 1 via the sprocket body 1a. Therefore, it is possible to reduce the size in the radial direction in addition to the axial direction of the apparatus and to facilitate product management.

  The present invention is not limited to the configuration of the above embodiment, and the permanent magnets 14 and 15 are used as the stator. However, other stators can be used.

The technical ideas of the invention other than the claims ascertained from the embodiment will be described below.
[Claim a] In the valve timing control apparatus for an internal combustion engine according to claim 1,
The intermediate rotating body is characterized in that a stepped small-diameter portion is formed on the tip side of the portion where the rotor is fixed, and a commutator unit in which the commutator is provided on the outer periphery is fixed to the small-diameter portion. A valve timing control device for an internal combustion engine.
[B] A valve timing control apparatus for an internal combustion engine according to claim a,
The valve timing control device for an internal combustion engine, wherein at least a part of the commutator unit is disposed so as to enter an inner peripheral portion of a portion of the coil opposite to the partition wall in the axial direction.

[Claim c] In the valve timing control apparatus for an internal combustion engine according to claim b,
A valve timing control device for an internal combustion engine, characterized in that varnish is filled between an outer periphery of the commutator unit and an inner peripheral portion of a portion of the coil opposite to the partition wall in the axial direction.

[Claim d] In the valve timing control apparatus for an internal combustion engine according to claim b,
An internal combustion engine characterized in that at least the outer periphery on the front end side of the housing structure is covered with a cover, and a second seal member is provided between the inner surface of the cover and the outer surface of the housing structure. Engine valve timing control device.

(Claim e) In the valve timing control apparatus for an internal combustion engine according to claim d,
The valve timing control device for an internal combustion engine, wherein the cover is provided with a power supply brush for the power supply mechanism, and the housing structure is provided with a slip ring that contacts the power supply brush.

[Claim f] In the valve timing control apparatus for an internal combustion engine according to claim e,
In the cover, a power supply brush unit in which the power supply brush is covered with an insulating material is fixed to a metal part, and a connector for connecting the power supply brush and the battery power source is covered with an insulating material on the power supply brush unit. A valve timing control device for an internal combustion engine.

[Claim g] In the valve timing control apparatus for an internal combustion engine according to claim e,
In the housing structure, a switching brush unit in which the switching brush is covered with an insulating material is fixed to a distal end side of a housing made of a metal material, and the slip ring is covered with the insulating material in the switching brush unit. A valve timing control device for an internal combustion engine.

(Claim h) In the valve timing control apparatus for an internal combustion engine according to claim 1,
A valve timing control device for an internal combustion engine, wherein the annular recess is formed in a stepped surface whose inner peripheral side is perpendicular to the bottom surface, and the outer peripheral side is formed in a diameter-enlarging shape with respect to the bottom surface. .

[Claim i] In the valve timing control apparatus for an internal combustion engine according to claim h,
The valve timing control device for an internal combustion engine, characterized in that an outer peripheral side of the annular recess is formed in an enlarged tapered surface.

[Claim j] The valve timing control apparatus for an internal combustion engine according to claim i,
A valve timing control device for an internal combustion engine, wherein a female screw hole into which a bolt for fixing the speed reduction mechanism is screwed is formed at a position on the outer peripheral side of the tapered surface of the annular recess of the partition wall.

1 ... Timing sprocket 1a ... Sprocket body (rotation transmission part)
DESCRIPTION OF SYMBOLS 1b ... Gear part 2 ... Cam shaft 2a ... Flange part 2b ... Stopper groove 2e ... Front end surface 3 ... Cover member 3a ... Expansion part 3b ... Cylindrical wall 3c ... Holding hole 4 ... Phase change mechanism 5 ... Housing 5a ... Housing Main body 5b ... Partition wall 5c ... Shaft insertion hole 5d ... Annular recess 5e ... Outer inner peripheral surface 5f ... Inner inner peripheral surface 7 ... Bolt 8 ... Deceleration mechanism 9 ... Follower member 10 ... Cam bolt 12 ... Electric motor 13 ... Motor shaft ( Intermediate rotating body)
14, 15 ... Permanent magnet 17 ... Iron core rotor (bobbin)
17a, 17b ... 1st, 2nd jaw part 18 ... Electromagnetic coil 18a, 18b ... Coil winding 18c ... End of coil wire 20 ... Ring member 21 ... Commutator 21a ... Folding part (coil connection part)
25a, 25b ... 1st brush (switching brush)
39 ... Eccentric shaft portion 46 ... Small diameter oil seal 54 ... Varnish S ... Annular space

Claims (3)

A driving rotating body to which rotational force is transmitted from the crankshaft;
A rotational force is transmitted from the drive rotator, and a driven rotator fixed to the camshaft;
An intermediate rotator provided to be rotatable relative to the drive rotator;
A reduction mechanism that decelerates the rotation of the intermediate rotator and transmits it to the driven rotator by rotating the intermediate rotator relative to the drive rotator;
An electric motor for rotating the intermediate rotor relative to the drive rotor;
A housing structure that is provided integrally with the drive rotator and in which the speed reduction mechanism and the electric motor are disposed adjacent to each other in the axial direction;
The interior of the housing structure is partitioned into a speed reduction mechanism housing chamber in which the speed reduction mechanism is housed and lubricating oil is supplied, and an electric motor housing chamber in which the electric motor is housed, and the electric motor housing chamber side A partition wall formed with an annular recess,
A seal member fixed to the inner peripheral surface of the partition wall and sliding relative to the outer periphery of the intermediate rotating body;
With
The electric motor is
A magnetic rotor fixed to the intermediate rotor and provided with a plurality of slots in the circumferential direction;
A coil wound through a slot formed in the rotor;
Permanent magnets having a plurality of magnetic poles arranged along the circumferential direction on the circumference of the electric motor housing chamber of the housing structure,
A commutator provided in the intermediate rotating body and electrically connected to the coil;
A switching brush provided in the housing structure and provided so as to be in contact with the commutator;
A power supply mechanism provided between the housing structure and an external device, and supplying a current from a battery power source to the coil via the switching brush;
In the coil, a portion located on the partition wall side in the axial direction is disposed in the annular recess, and a portion on the opposite side to the partition wall is wound from the inner peripheral side with respect to the annular recess. A valve timing control device for an internal combustion engine. An internal combustion engine valve provided with an electric motor for changing valve timing, and a speed reduction mechanism for reducing the rotational force of the electric motor while being lubricated with lubricating oil and transmitting it to the camshaft via a partition wall A timing control device,
An annular recess is formed on the electric motor side of the partition wall, and a seal member is provided on the inner peripheral surface of the partition wall to prevent leakage of lubricating oil of the speed reduction mechanism to the electric motor,
The coil of the electric motor is wound at a position where the part on the partition wall side is fitted into the annular recess, while the part on the side opposite to the partition wall is wound in a wider range in the radial direction than the annular recess. A valve timing control device for an internal combustion engine, wherein the valve timing control device is wound so as to be axially asymmetric with the part on the partition wall side. An internal combustion engine valve timing control device in which an electric motor that rotates and changes valve timing and a speed reduction mechanism that decelerates the rotational force of the electric motor and transmits it to a camshaft are provided adjacent to each other through a partition wall. There,
An annular recess is formed on the electric motor side of the partition wall, and a seal member for preventing the lubricating oil in the speed reduction mechanism from leaking to the electric motor side is provided on the inner peripheral surface of the partition wall,
The valve timing control device for an internal combustion engine, wherein the coil of the electric motor is disposed so as to be fitted into the annular recess from the axial direction.

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