JP2022155123A - Hydraulic VVT device - Google Patents

Abstract

To prevent malfunctions caused by a metallic powder contained in an oil discharged from a spool in a solenoid unit which drives the spool which is an oil control valve of a VVT device.SOLUTION: A solenoid unit 2 includes an armature 40, a center pin 41, and a pole piece 43. The pole piece 43 is fitted in an inner case 36. The pole piece 43 has an inward-facing cylinder part 46. An oil discharge hole 50 is formed at a lower end of a flange part 45a in the pole piece 43. Even if a metallic powder is mixed with an oil, the metallic powder does not stay within the pole piece 43 and flows with the oil flow to be discharged from the oil discharge hole 50 to the outside through first and second gaps (oil discharge passages) 48, 49. Thus, even if the metallic powder is mixed with the oil, a situation, in which the metallic powder enters a gap between a bearing tube 39 and the armature 40 to cause malfunctions, does not occur.SELECTED DRAWING: Figure 2

Description

The present invention relates to a hydraulic VVT device (variable valve timing device) for controlling valve opening/closing timing by advancing or retarding a camshaft with respect to a crankshaft in an engine.

2. Description of the Related Art In a gasoline engine or a diesel engine, a VVT device is widely used to advance or retard a camshaft in order to control the opening/closing timing of a valve. There are two types of VVT devices: hydraulic type and electric type. In the hydraulic VVT device, a trilobal or four-leaf type that rotates together with a camshaft is installed inside a housing that rotates together with a sprocket around which a timing chain is wound. A leaf-shaped rotor is arranged to be relatively rotatable, and pressurized oil is selectively supplied to an advance chamber and a retard chamber formed between the rotor and the housing to advance the camshaft. I'm delaying it. However, there is also a type that only advances the angle from the reference state.

An oil control valve (OCV) is used to switch the supply of oil to the advance chamber and the retard chamber. Oil control valves also have various structures, and as an example, Patent Document 1 discloses that an oil control valve (spool) is arranged concentrically with a rotor of a VVT device. On the other hand, Patent Document 2 discloses that an oil control valve is provided in a cylinder block.

JP 2019-060214 A JP 2003-214552 A

Although the details of the oil control valve are not disclosed in Patent Document 1, the oil control valve is composed of a spool that slides in the direction concentric with the camshaft, and when the spool is pushed by the center pin of the solenoid unit, the spool slides. As a result, the pressure chamber formed on the outer peripheral surface of the spool selectively communicates with the oil port of the advance chamber or the oil port of the retard chamber, and the inside of the spool is connected to the oil port of the advance chamber or the retard chamber. is adapted to selectively communicate with the oil port of the

That is, when the pressure chamber of the spool communicates with the oil port of the advance chamber, the inside of the spool communicates with the oil port of the advance chamber, and conversely, the pressure chamber of the spool communicates with the oil port of the retard chamber. Then, the inside of the spool communicates with the oil port of the retard chamber, so that the housing and rotor rotate together and rotate relative to each other, and the camshaft advances with respect to the sprocket (crankshaft). or retard. A neutral state in which the same amount of oil is accumulated in the advance chamber and the retard chamber is also selectable.

As disclosed in Patent Document 2, the spool is urged in the forward direction by a spring, and the electromagnetic solenoid is energized to drive the center pin to push the spool, or the electromagnetic solenoid is turned off. The oil flow is controlled by springing back the spool.

In Patent Document 1, the oil control valve (spool) is built into the main body of the VVT device and is an OCV integrated type, so compared to the case where it is attached to the cylinder block as in Patent Document 2, the advantage is that the engine can be made more compact. There is Further, when the oil control valve is provided in the main body of the VVT device as in Patent Document 1, the solenoid unit is provided in the chain cover (front cover) that covers the timing chain, but the solenoid unit is fixed to the chain cover. Since it is easy to install, the workability of assembly is also excellent.

In Patent Document 1, the oil returned to the inside of the spool is used to lubricate the camshaft. and flows down to Onlupan through the space covered by the chain cover.

Therefore, in this case, the oil discharged from the spool falls on the center pin of the solenoid unit, but since there is a slight clearance between the center pin and the pole piece (guide lid) through which the center pin is inserted, the oil flows through this clearance. may get inside the pole piece. Conventionally, the pole piece has an oil drain hole that communicates with the inside of the pole piece. In some cases, the armature (movable magnetic body, plunger) that is in the

When the inventors of the present application investigated the cause of this point, it was found that fine metal powder with a particle size of several tens of μm clogs the gap between the armature and the bearing tube (guide sleeve) that slidably holds the armature. phenomenon was observed. The component of the metal powder is iron, and it is presumed that the metal powder that was not removed during the engine manufacturing process circulates in the oil and has an adverse effect on the solenoid unit.

The present invention was made against the background of such knowledge and research. In a VVT device in which a spool is arranged concentrically with a camshaft and a solenoid unit is arranged outside thereof, oil containing metal powder is applied to the solenoid. To disclose a technique that greatly suppresses intrusion into the inside of a pole piece in a unit and does not adversely affect the sliding of an armature even if oil mixed with metal powder intrudes.

The present invention relates to a hydraulic VVT device, and this hydraulic VVT device
"In a casing having an opening facing the camshaft, an armature that slides coaxially with the camshaft, a bearing tube that embraces the armature from the outside and guides the slide, and an armature that extends from the camshaft. and a pole piece for slidably holding the center pin protruding in the direction of
The pole piece has a substrate through which the center pin penetrates directly or via a bush, and an inward cylindrical portion protruding from the substrate toward the armature, and the substrate includes the inward cylindrical portion. has a flange protruding outside the
The forward and backward movement of the center pin controls the sliding of the spool in the hydraulic drive unit, and the used oil in the hydraulic drive unit is discharged from the internal space of the spool to the pole piece side.
In the configuration
"At the bottom of the flange portion of the pole piece, an oil discharge hole is formed to discharge oil that has entered the inside of the pole piece."
It has a configuration.

In the present invention, the position of the oil discharge hole is preferably lower than the armature, and more preferably directly below the center pin. The "lower portion" specified in the claims can be defined as, for example, a portion below the axis of the center pin, but preferably a position near the inner peripheral lower end of the inward cylindrical portion.

The present invention can be developed in various ways. As an example, in claim 2,
"At least in the lower part of the outer peripheral side of the inward cylindrical portion of the pole piece, an oil discharge passage through which the oil that has flowed out over the inward cylindrical portion flows toward the discharge hole is lowered as it approaches the oil discharge hole. It is formed in an inclined posture so that
It is configured.

Furthermore, in claim 3, in claim 1 or 2,
"The outer peripheral surface of the inward cylindrical portion of the pole piece is formed in a tapered shape that expands in diameter toward the substrate, and an annular oil discharge passage is formed outside the outer peripheral surface of the inward cylindrical portion of the pole piece. and the oil discharge hole is formed by partially excising the outer peripheral surface of the inward cylindrical portion.”
It is configured.

In the present invention, the number of oil discharge holes is not limited to one. It is also possible to form a plurality of them just below the center pin. In this case, the pole piece should be aligned so that the oil drain hole is directly underneath. For example, 4 to 6 oil discharge holes may be formed at equal intervals in the circumferential direction, and one of the oil discharge holes may be positioned at the bottom regardless of the position of the pole piece. It is possible. In this case, the positioning of the pole piece is not necessary, so the labor for assembly can be reduced.

In the present invention, since the oil discharge hole is located at the bottom of the pole piece and is open to the flange, even if oil containing metal powder enters the inside of the pole piece, the metal powder is forced out of the oil discharge hole together with the oil by gravity. flow out. Therefore, it is possible to prevent or remarkably suppress the accumulation of metal powder inside the pole piece, thereby preventing the metal powder from entering between the armature and the bearing tube, thereby preventing the armature from operating. This ensures that the reliability of the VVT device can be improved.

Also, if the oil drain hole communicates with the inside of the pole piece, it is possible that the oil that has fallen from the spool onto the outer surface of the pole piece may flow down into the oil drain hole. Even if the oil flows down into the oil discharge hole, it is difficult for the oil to enter the pole piece through the oil discharge hole. Therefore, the intrusion of oil and metal powder into the inside of the pole piece itself can be significantly reduced.

Furthermore, the clearance between the center pin and the pole piece is slight, and even if oil enters, the amount is not large. If oil easily enters the inside of the pole piece through the discharge hole, the amount of metal powder that enters the inside of the armature will increase. Therefore, the intrusion of metal powder itself can be greatly suppressed.

Now, it is not impossible to prevent oil from entering the inside of the pole piece. For example, if an oil seal is fitted to the pole piece and the center pin is closely fitted to the oil seal, it can be said that the intrusion of oil and metal powder can be prevented. However, when an oil seal is installed, the sliding resistance of the center pin increases, which hinders the quick movement of the armature and may deteriorate the responsiveness of the valve opening/closing timing control. If a solenoid is provided, there is concern about the occurrence of new problems such as an increase in the size of the solenoid unit and deterioration in fuel consumption.

In contrast, in the present invention, even if oil enters the inside of the pole piece, there is no adverse effect, so the sliding resistance of the center pin can be minimized. The reliability of the solenoid unit can be improved without deteriorating the control responsiveness of the camshaft.

When the oil discharge passage is slanted downward as in claim 2, the oil and the metal powder can easily flow down due to gravity, so the metal powder can be placed on the flow of the oil and quickly discharged. Also, even if the oil runs down the surface of the pole piece and reaches the oil discharge hole, the oil does not enter the inside of the pole piece through the oil discharge hole, so metal powder does not enter the pole piece through the oil discharge hole. It also has the advantage of preventing

Furthermore, in the invention of claim 3, since the oil discharge passage is formed along the entire circumference of the inward cylindrical portion, the oil and metal powder flow into the oil discharge hole quickly, and the metal powder is discharged. can ensure In addition, since the oil discharge hole cuts into a part of the outer peripheral surface of the inward cylinder, the cross-sectional area of the oil discharge passage directly above the oil discharge hole becomes large, so that the metal powder can be carried on the oil flow. It can promote the effect of discharging.

It is a longitudinal side view of a 1st embodiment. FIG. 2 is an enlarged view of a main portion of FIG. 1; (A) is a bottom perspective view of a pole piece, and (B) is an enlarged view of a main portion of FIG. 2. FIG. (A) is a vertical cross-sectional side view of a main part of a second embodiment, and (B) is a vertical cross-sectional side view of a main part of a third embodiment. It is a front view of a 4th embodiment.

Next, embodiments of the present invention will be described based on the drawings. In the following description, terms such as front-rear and up-down are used to specify directions, and the front-rear direction is the axial direction of the camshaft (the direction of the crankshaft), and the vertical direction is the vertical direction. Regarding the front and rear, when looking at the transmission case from the timing chain side, the front is the front and the back is the rear.

(1). Basic structure of VVT device First, the basic structure of the VVT device will be described mainly with reference to FIG. The VVT device consists of a hydraulic drive unit 1 having a hydraulic flow path switching mechanism, and a solenoid unit 2 for controlling the hydraulic drive unit 1. The hydraulic drive unit 1 is attached to a cam shaft 3, and the solenoid The unit 2 is fixed to the chain cover 4 with bolts. The front wall of the head cover 5 overlaps the upper end of the chain cover 4 .

A front portion of the camshaft 3 is rotatably held by a bearing portion 7 formed in the cylinder head 6 and a front cam cap 8 . The camshaft 3 has a front journal portion 3a rotatably held by the front cam cap 8, and a projecting portion 3b projecting forward from the cylinder head 6 and the front cam cap 8. These front journal portions 3a and projecting portion 3b have a forward opening hole 9 and are cylindrical.

A center bolt 10 is screwed from the front into a forward opening hole 9 of the camshaft 3, a rotor 11 is fitted to the center bolt 10 from the outside, and the rotor 11 is covered with a housing 12 from the outside. On the other hand, a chain sprocket 14 around which a timing chain 13 is wound is fitted to the projecting portion 3b of the camshaft 3 so as to be relatively rotatable from the outside. 14 are integrally fixed with a plurality of bolts 16 spaced apart in the circumferential direction. Therefore, the housing 12 rotates together with the chain sprocket 14 .

The rotor 11 is pressed and held at the front end of the cam shaft 3 by a flange 10 a provided on the center bolt 10 . Further, the rotor 11 and the camshaft 3 are held so as not to rotate relative to each other by a positioning pin 17 penetrating through both. Therefore, the rotor 11 rotates together with the camshaft 3 . The outer plate 15 is arranged to surround the flange 10a of the center bolt 10 from the outside.

Although not explicitly shown in the figures, the rotor 11 is vane-shaped with a plurality of radially projecting outward protrusions, while the inner circumference of the housing 12 has adjacent outer portions of the rotor 11 . It has a plurality of inward projections positioned between the projections, and an advance chamber and a retard chamber are formed between the outward projections and the inward projections. An oil port through which oil flows in and out is opened in each of the advance chamber and the retard chamber.

The center bolt 10 is formed in a cylindrical shape that is open forward and backward, and a sleeve 19 having a bottom plate 18 is fitted therein, and a spool 20 is arranged inside the sleeve 19 so as to be slidable forward and backward. . The rear end of the sleeve 19 is supported by a stopper 21 on an inward flange 22 at the rear end of the center bolt 10 , and the front end is retained by a snap ring 23 attached to the inner surface of the front end of the center bolt 10 .

The spool 20 is urged forward by a spring 24 supported by the bottom plate 18 of the sleeve 19, and is retained by the snap ring 23 described above. Although it is a schematic display, oil ports 25 and 26 are formed on the outer circumference of the spool 20 and the outer circumference of the sleeve 19. As the spool 20 moves back and forth, the oil port 25 of the spool 20 is moved to the two positions of the sleeve 19. The rotor 11 and the housing 12 are selectively communicated with the two oil ports 26, and the rotor 11 and the housing 12 rotate relatively. controlled.

Oil for driving the hydraulic drive unit 1 is supplied from an oil gallery 27 a provided in the cylinder head 6 . The oil sent from the oil gallery 27a passes through a groove passage 27b formed in the upper surface of the cylinder head 6, an annular passage 28 formed in the camshaft 3, a radial passage 29 formed in the camshaft 3, and a forward-facing portion of the camshaft 3. It flows into the center bolt 10 through the opening hole 9 . A filter 30 and a plate-like check valve 31 are arranged at the rear end of the center bolt 10, and are held by a stopper 21 so as not to be displaced.

Although not shown in the drawings, the stopper 21 and the sleeve 19 are formed with oil passages for guiding oil to the oil port 25 of the spool 20 . The spool 20 is hollow and open rearward, has an oil port 25 formed on its outer peripheral surface, and further has a return passage (not shown) communicating inside and outside. Further, the tip of the spool 20 is a small-diameter head portion 20 a , and the head portion 20 a protrudes forward from the outer plate 15 . The inside of the spool 20 is vertically opened behind the head portion 20a, and this opening serves as an oil escape port 20b (see FIG. 2).

An annular wall 10b surrounding the head portion 20a of the spool 20 is formed at the front end of the center bolt 10, and the oil discharged from the spool 20 flows downward from the edge of the annular wall 10b.

The solenoid unit 2 includes an outer case 35 with a rearward opening fitted from the front into a mounting hole 34 formed in the chain cover 4, and an inner case 36 with a forward opening fitted into the outer case 36 from the rear. and the inner case 36 constitute a casing.

Further, the solenoid unit 2 includes an annular coil 37 arranged inside the inner case 36, a fixed magnetic body (core) 38 held by the coil 37, and a bearing tube (guide sleeve) surrounded by the fixed magnetic body 38. ) 39, an armature (movable magnetic body, plunger) 40 slidably held by the bearing tube 39, a center pin (drive pin) 41 projecting backward from the armature 40, and the center pin 41 through a bush 42. and a pole piece (guide lid) 43 slidably inserted through.

The center pin 41 is arranged concentrically with the spool 20, and is slightly spaced from the spool 20 in the retracted state. When the coil 37 is energized, the armature 40 and the center pin 41 advance and the spool 20 retreats. A gap is provided between the annular wall 10b of the center bolt 10 and the pole piece 43, and the oil flows downward through the gap. The outer case 35 is provided with a connecting portion 44 for connecting a connector.

(2). Polepiece Armature Next, the polepiece 43 and the armature 40 will be described mainly with reference to FIGS. The pole piece 43 has a disk-shaped base plate 45 and an inward cylindrical portion 46 projecting forward therefrom. The substrate 45 has a flange portion 45a projecting outwardly from the inward cylindrical portion 46, and the flange portion 45a is fitted into a circular opening formed in the inner case 36 by force fitting.

The inward cylindrical portion 46 of the pole piece 43 has a straight inner peripheral surface parallel to the axis of the center pin 41 , and an outer peripheral surface 46 a tapered toward the flange portion 45 a of the substrate 45 . ing. On the other hand, the bearing tube 39 has a bottom portion 39a at its front end and is open rearward. At the front end of the bearing tube 39, there are formed an outward stepped portion 39b, a tapered portion 39c with a rearwardly enlarged diameter continuous with the outward stepped portion 39b, and a flange portion 39d provided at the opening edge of the tapered portion 39c. The flange portion 39 d contacts the flange portion 45 a of the pole piece 43 . Therefore, the bearing tube 39 is held by the pole piece 43 so as not to move forward or backward.

The inner diameter of the inward cylindrical portion 46 of the pole piece 43 is slightly larger than the inner diameter of the straight portion of the bearing tube 39 (or the outer diameter of the armature 40). Therefore, the lower end of the front end of the inward cylindrical portion 46 is slightly lower than the lower end of the straight portion of the bearing tube 39 .

An annular first gap 48 is formed between the inward cylindrical portion 46 of the pole piece 43 and the outward stepped portion 39b of the bearing tube 39 so that the inward cylindrical portion 46 of the pole piece 43 and the bearing tube 39 are separated. A tapered annular second gap 49 is provided between the tapered portion 39c and the tapered portion 39c.

Further, an oil discharge hole 50 opening forward and backward is formed at the lower end of the flange portion 45a of the pole piece 43. As shown in FIG. In this case, the oil discharge hole 50 is formed by partially removing the outer peripheral surface 46a of the inward cylindrical portion 46. As shown in FIG. For this reason, a downwardly opening groove 51 is formed in the outer peripheral surface 46 a of the inward cylindrical portion 46 . Although the oil discharge hole 50 is arranged directly below the center pin 41, it need not be strictly positioned directly below, and may be positioned approximately below the center pin 41 when visually observed.

The spool 20 moves back and forth in conjunction with the back and forth movement of the armature 40, and this advance/retard control of the cam shaft 3 is performed. A slight clearance is provided between it and the bush 42 . Therefore, oil may seep into the pole piece 43 through the clearance between the center pin 41 and the bush 42 .

The exuded oil flows down to the lower end of the inward tubular portion 46 , but since the oil discharge hole 50 is formed in the lower end of the flange portion 45 a of the pole piece 43 , the oil flows along the inner surface of the inward tubular portion 46 . The oil flows into the oil discharge hole 50 through the first and second gaps 48 and 49 and then flows downward through the space surrounded by the chain cover 4 . If metal powder is mixed in the oil, the metal powder is discharged along with the flow of the oil.

In this case, since the lower end of the tip portion of the inner peripheral surface of the inward cylindrical portion 46 is located slightly below the lower end of the inner peripheral surface of the bearing tube 39 , oil and metal powder do not flow between the bearing tube 39 and the armature 40 . It does not intrude into the gap between Therefore, even if metal powder is mixed in the oil that has entered the inside of the pole piece 43, the metal powder will not enter the gap between the bearing tube 39 and the armature 40, causing the armature 40 to malfunction. never.

Therefore, the clearance between the center pin 41 and the bush 42 is roughened to ensure smooth sliding of the center pin 41 and smooth sliding of the armature 40, thereby maintaining high reliability. Furthermore, if the oil discharge hole 50 is arranged directly below the center pin 41, the entire amount of the oil is discharged without accumulating inside the inward cylinder portion 46, so that the metal powder mixed in the oil is discharged by gravity into the inward cylinder. It is possible to prevent the occurrence of the phenomenon that metal powder is deposited on the lower end of the portion 46, so that the metal powder can be quickly discharged without leakage. This embodiment is also useful in this respect.

Also, although the oil discharged from the spool 20 may splash on the oil discharge hole 50, since the oil discharge hole 50 is located below the inner peripheral surface of the inward cylindrical portion 46, the oil does not flow through the oil discharge hole. A phenomenon in which the air flows backward through the pole piece 43 and enters the inside of the pole piece 43 does not occur. Therefore, the intrusion of oil and metal powder into the inside of the pole piece 43 itself is remarkably suppressed.

The armature 40 advances toward the inside of the inward cylindrical portion 46, but the amount of oil and metal powder that enters the inside of the pole piece 43 is small in the first place, and even if the oil and metal powder enter, Since they are discharged, oil and metal powder do not accumulate at the lower end of the inward cylindrical portion 46, or the amount of such accumulation is very small. Therefore, it is possible to prevent a phenomenon in which oil adheres to the lower surface of the advanced armature 40 and metal powder contained in the oil enters the gap between the armature 40 and the bearing tube 39 .

In the present embodiment, the lower ends of the first and second gaps 48 and 49 constitute the oil discharge passage described in the claims, but the second gap 49 is tapered to increase its diameter toward the rear. Therefore, the oil discharge passage is inclined downward. Therefore, the oil and the metal powder are smoothly discharged, and the phenomenon that the oil containing the metal powder enters the inside of the pole piece 43 through the oil discharge hole 50 does not occur.

When the oil discharge hole 50 is widened to a part of the inward cylindrical portion 46 as in the embodiment, the diameter of the oil discharge hole 50 can be increased as much as possible while communicating with the oil discharge passage (second gap 49) in its entirety. Therefore, it is possible to enhance the effect of discharging the metal powder on the flow of the oil.

The annular wall 10b of the center bolt 10 and the substrate 45 of the pole piece 43 have substantially the same outer diameter. Therefore, the oil that has flowed down from the annular wall 10b licks the oil discharge hole 50 and flows down, but the oil is sucked downward from the oil discharge hole 50 due to the ejector effect of the flow of the oil discharged from the annular wall 10b. phenomena can occur. In this respect as well, it can be said that the discharge of oil from the oil discharge hole 50 can be ensured.

Although the oil drain hole 50 is formed by drilling, if the drill is applied to the base plate 45 from the outside (from the rear in the state shown in the figure), the oil drain hole 50 can be precisely drilled without causing slippage of the drill. It has the advantage of being able to perforate.

(4). Other Embodiments FIGS. 4 and 5 show other embodiments. In the second embodiment shown in FIG. 4A, a notch 52 opening forward is formed in the lower end of the inward cylindrical portion 46 of the pole piece 43 as an oil discharge auxiliary passage. By forming in this way, it is possible to more reliably prevent metal powder from reaching the armature 40 .

In the third embodiment shown in FIG. 4(B), the inwardly directed cylindrical portion 46 is formed with an internal/external communication hole 53 that opens to the inside and outside (opens vertically). In this embodiment, the oil and metal powder that have entered the inside of the pole piece 43 are discharged through the inner/outer passage hole 53 and the second gap 49 to reach the oil discharge hole 50 . Therefore, in this embodiment, there is an advantage that the metal powder can be rapidly guided to the oil discharge hole 50 and discharged. In the embodiment of FIGS. 4A and 4B, even if the tip of the inward cylindrical portion 46 is in contact with the outward stepped portion 39b of the bearing tube 39, the metal powder can be discharged by the oil flow.

In FIG. 4(B), the oil passage hole 53 is formed at the base of the inward cylindrical portion 46, but its position (front and rear positions) can be set arbitrarily. Further, when the inner/outer communicating hole 53 is formed in the base portion of the inward cylindrical portion 46, the inner peripheral surface 46b of the inward cylindrical portion 46 is formed into a tapered surface that widens rearward as indicated by the dashed line. If the internal/external communication hole 53 is opened at the maximum diameter of the armature 40, the oil level can be greatly lowered, which has the advantage of more reliably preventing metal powder from coming into contact with the outer peripheral surface of the armature 40. The embodiment of FIG. 4 can also be applied to the first embodiment and the fourth embodiment described later.

In the fourth embodiment shown in FIG. 5, four oil discharge holes 50 are formed at equal intervals in the circumferential direction. With this configuration, one of the oil discharge holes 50 is positioned below the pole piece 43 regardless of the attitude of the pole piece 43, so that the oil can be discharged without requiring time and effort to adjust the attitude. can ensure

FIG. 5 shows a state in which the two oil discharge holes 50 are at the same height at the bottom, and one oil discharge hole 50 is positioned further downward when rotated left or right from this state. Therefore, in the state of FIG. 5, the oil drain hole 50 is positioned at the highest position in the lower portion.

The oil and metal powder accumulated inside the pole piece 43 climbs over the tip of the inward cylindrical portion 46, accumulates in the second gap 49 (see the hatching on the lower right), and is discharged from the oil discharge hole 50. Since the oil discharge hole 50 is formed in the flange portion 45a of the pole piece 43, the oil discharge hole 50 is largely displaced downward. (See left-sloping hatching). Therefore, in this embodiment as well, the adhesion of metal powder to the armature 40 can be prevented or significantly suppressed.

In FIG. 5, for comparison, the state in which the oil discharge hole 50 is arranged inside the inwardly directed cylindrical portion 46 is indicated by a dashed line. Since the armature 40 is always positioned above the lower end of the armature 40, the oil cannot be discharged until the armature 40 is partially submerged. Therefore, a metal powder retention phenomenon occurs, increasing the chances of the metal powder entering the gap between the armature 40 and the bearing tube 39 .

In addition, since the oil discharge hole 50 is positioned above the lower end of the inner surface of the inward cylindrical portion 46, the heavy metal powder cannot reach the oil discharge hole 50, and the metal powder does not reach the inside of the inward cylindrical portion 46. As a result, it can be said that the accumulated metal powder is likely to enter the gap between the armature 40 and the bearing tube 39 due to vibration.

In contrast, in the fourth embodiment, not only can the amount of oil accumulated in the inward cylindrical portion 46 be significantly reduced, but even if the metal powder and oil accumulate in the inward cylindrical portion 46, the metal powder is The oil is discharged from the tip of the inward cylindrical portion 46 along with the oil flow. Therefore, it is possible to ensure the operation of the armature 40 while eliminating the trouble of assembling by forming a plurality of oil discharge holes 50 .

In addition, since the plurality of oil discharge holes 50 are formed in the flange 45a respectively, even if oil enters the oil discharge holes 50 positioned at the upper part, the oil flows downward along the outside of the inwardly directed cylindrical portion 46. , oil and metal powder do not enter the interior of the inward cylindrical portion 46 .
Furthermore, since the oil discharge hole 50 is far away from the center pin 41, it is outside the area where the oil discharged from the spool 20 splashes. Therefore, even if a plurality of oil discharge holes 50 are formed, it can be said that oil does not actually flow into the oil discharge holes positioned at the top.

Although the embodiments of the present invention have been described above, the present invention can be embodied in various other ways. For example, the oil drain hole can be formed in the form of a cutout opening on the outer circumference of the flange. The specific configurations of the hydraulic drive unit and the solenoid unit are not limited to the embodiments, and can be variously changed.

The present invention can be embodied in a hydraulic VVT device controlled by a solenoid unit. Therefore, it can be used industrially.

1 Hydraulic Drive Unit 2 Solenoid Unit 3 Camshaft 4 Chain Cover 6 Cylinder Head 8 Front Cam Cap 10 Center Bolt 11 Rotor 12 Housing 13 Timing Chain 14 Chain Sprocket 15 Outer Plate 19 Sleeve 20 Spool 35 Outer Sooth Constituting Casing 36 Casing Constituent inner sleeve 37 coil 39 bearing tube 40 armature 41 center pin 42 bush 43 pole piece 45 base plate 45a flange portion 46 inward cylindrical portion 46a outer peripheral surface 48 annular first gap forming an oil discharge passage 49 forming an oil discharge passage Annular second gap 50 Oil discharge hole 51 Groove

Claims (3)

A casing having an opening facing the camshaft contains an armature that slides coaxially with the camshaft, a bearing tube that holds the armature from the outside and guides the slide, and a shaft extending from the armature to the camshaft. A pole piece for slidably holding a center pin protruding in the direction is arranged,
The pole piece has a substrate through which the center pin penetrates directly or via a bush, and an inward cylindrical portion protruding from the substrate toward the armature, and the substrate includes the inward cylindrical portion. has a flange protruding outside the
The forward and backward movement of the center pin controls the sliding of the spool in the hydraulic drive unit, and the used oil in the hydraulic drive unit is discharged from the internal space of the spool to the pole piece side,
An oil discharge hole for discharging oil that has entered the inside of the pole piece is formed in the lower portion of the flange portion of the pole piece.
Hydraulic VVT device. At least in the lower part of the outer peripheral side of the inward cylindrical portion of the pole piece, an oil discharge passage through which the oil that has flowed out over the inward cylindrical portion flows toward the discharge hole becomes lower as it approaches the oil discharge hole. It is formed in a tilted posture,
Hydraulic VVT device according to claim 1. The outer peripheral surface of the inward cylindrical portion of the pole piece is formed in a tapered shape that expands in diameter toward the substrate, and an annular oil discharge passage is formed outside the outer peripheral surface of the inward cylindrical portion of the pole piece. and the oil discharge hole is formed by partially excising the outer peripheral surface of the inward cylindrical portion,
A hydraulic VVT device according to claim 1 or 2.

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