JP4165395B2 - Oil flow control valve - Google Patents

Description

  The present invention relates to an oil flow control valve (hereinafter referred to as OCV) that switches the flow of oil by the operation of an electromagnetic actuator, and in particular, a variable valve timing device (hereinafter referred to as VVT) that varies the advance phase of a camshaft by hydraulic pressure. The present invention relates to a technique suitable for use.

The OCV is an electromagnetic valve that controls an oil pressure supply direction, a supply pressure, and the like by switching an input / output port formed in a sleeve by displacing a spool of a spool valve in an axial direction by an electromagnetic actuator.
The electromagnetic actuator includes a first volume fluctuation chamber in which a magnetic attraction gap (main gap) is formed on the side of the plunger (member for magnetically attracting the plunger), and a second side on a side different from the first volume fluctuation chamber of the plunger. A volume fluctuation chamber is provided.
When the plunger is displaced in the axial direction by the operation of the electromagnetic actuator, the volumes of the first and second volume fluctuation chambers change.

(First prior art)
The first and second volume fluctuation chambers are communicated with the atmosphere, and the communication between the spool valve and the electromagnetic actuator is blocked by a diaphragm to prevent oil supplied and discharged inside the spool valve from entering the electromagnetic actuator. A technique has been proposed (see, for example, Patent Document 1).
However, in the OCV that cuts off the communication between the spool valve and the electromagnetic actuator using a diaphragm, a load such as a restoring force of the diaphragm is applied to the plunger. Therefore, the movement of the plunger is inhibited as the plunger stroke increases.
Further, since the fatigue of the diaphragm increases as the number of strokes of the plunger increases, the durability of the OCV is shortened by the fatigue of the diaphragm.

(Second prior art)
Unlike OCV using a diaphragm, one or a plurality of breathing holes communicating with the external low-pressure oil passage are formed in the sleeve, and the breathing holes and the first and second volume fluctuation chambers are communicated with each other via the breathing passage. 1. A technique for supplying and discharging oil to and from the second volume fluctuation chamber has been proposed (see, for example, Patent Document 2).
In the OCV that supplies and discharges oil to and from the first and second volume fluctuation chambers, when the plunger is displaced in the axial direction by the operation of the electromagnetic actuator, the oil flows to the first and second volume fluctuation chambers through the breathing holes and the breathing passage. Since it is supplied and discharged, there is a possibility that magnetic foreign substances (abrasion powder, cutting powder, etc.) contained in the oil may enter the first and second volume fluctuation chambers together with the oil.

The first and second volume fluctuation chambers are inside the electromagnetic actuator. When a magnetic foreign substance (iron powder, iron piece, etc.) enters the first and second volume fluctuation chambers, the magnetic foreign substance that has entered the part of the magnetic circuit. May be configured.
In particular, when a magnetic foreign object enters the first volume fluctuation chamber and a magnetic flux shortcut due to the magnetic foreign substance is formed in the magnetic attraction gap between the stator and the plunger, the flow of magnetic flux becomes unbalanced, and the side force is applied to the plunger. Occurring, the sliding resistance of the plunger is increased, and the smooth movement of the plunger is hindered.
JP-A-11-210919 Japanese Patent Laid-Open No. 2001-18779

As described above, in the OCV that uses a diaphragm to prevent oil from entering the electromagnetic actuator, as the plunger stroke increases, the movement of the plunger is inhibited and there is a problem in durability.
In the OCV that supplies and discharges oil to and from the first volume fluctuation chamber, a magnetic flux shortcut caused by the magnetic foreign matter is formed in the magnetic attraction gap by the magnetic foreign matter contained in the oil, and the smooth movement of the plunger is hindered.
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an OCV that can prevent magnetic foreign matter from entering the first volume fluctuation chamber in which a magnetic attraction gap is formed without using a diaphragm. It is to provide.

[Means of claim 1]
The OCV adopting the means of claim 1 forms a plunger by combining the first and second plungers through which the lines of magnetic force generated by the coil pass, and is formed by a gap between the first and second plungers to generate the coil. The first volume fluctuation chamber and the breathing hole communicate with each other through the first magnetic foreign matter capturing passage through which the magnetic lines of force traverse.
By providing in this way, the magnetic foreign matter contained in the oil supplied to and discharged from the first volume fluctuation chamber is trapped in the first magnetic foreign matter trapping passage by the magnetic force generated by the coil. Intrusion of magnetic foreign objects can be prevented.
As a result, since the magnetic flux shortcut due to the magnetic foreign matter is not formed in the magnetic attraction gap, the magnetic flux that magnetically attracts the plunger is not unbalanced, and the plunger can be smoothly moved over a long period of time.
Further, since no diaphragm is used, there is no problem that the movement of the plunger is obstructed by the diaphragm, and there is no problem that the life of the OCV is shortened due to fatigue of the diaphragm.

[Means of claim 2]
The OCV adopting the means of claim 2 is such that the passage cross section of the first magnetic foreign matter trapping passage is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap.
Since the magnetic force becomes strong in the narrow gap, the magnetic foreign matter mixed in the oil can be reliably caught by the strong magnetic force. As the accumulation of foreign matter progresses, the magnetic foreign matter deposit site moves to a wide gap thereafter. Thereby, a magnetic foreign material can be captured stably for a long time.
In addition, the wide gap can secure a space for oil to flow at least in the center of the wide gap even when the magnetic foreign matter is adsorbed by the magnetic force in the surroundings. 1 There is no problem that the magnetic foreign matter catching passage is clogged.
Thus, by providing the passage cross section of the first magnetic foreign matter capturing passage in a gradually deforming shape that shifts from a narrow gap to a wide gap, the first magnetic foreign matter catching path is surely captured and the first magnetic foreign matter catching path is attracted by the adsorbed magnetic foreign matter. It is possible to achieve both the prevention of clogging of the foreign matter capturing passage.

[Means of claim 3]
The OCV adopting the means of claim 3 constitutes a plunger by combining the first to third plungers through which the magnetic lines of force generated by the coils respectively pass, and the gap between the first and third plungers, or the second and third The second volume fluctuation chamber and the breathing hole communicate with each other through the second magnetic foreign matter capturing passage formed by at least one of the plunger gaps.
By providing in this way, the magnetic foreign matter contained in the oil supplied to and discharged from the second volume fluctuation chamber is trapped in the second magnetic foreign matter trapping passage by the magnetic force generated by the coil. Intrusion of magnetic foreign objects can be prevented.
That is, intrusion of magnetic foreign matter is prevented in the second volume fluctuation chamber together with the first volume fluctuation chamber.
As a result, it is possible to prevent the occurrence of OCV malfunction caused by the intrusion of magnetic foreign matter into the first and second volume fluctuation chambers, and maintain the required OCV characteristics over a long period of time.

[Means of claim 4]
The OCV adopting the means of claim 4 is such that the passage cross section of the second magnetic foreign matter trapping passage is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap.
Since the narrow gap has the same magnetic force as the above-described means of claim 2, the magnetic foreign matter mixed in the oil can be reliably caught by the strong magnetic force. As the accumulation of foreign matter progresses, the magnetic foreign matter deposit site moves to a wide gap thereafter. Thereby, a magnetic foreign material can be captured stably for a long time.
Further, as in the above-described means of claim 2, the wide gap can secure a space for oil to flow at least in the central portion of the wide gap even when the magnetic foreign matter is adsorbed by a magnetic force in the surrounding area. There is no problem that the second magnetic foreign matter catching path is clogged by the magnetic foreign matter caught in the foreign matter catching path.
Thus, by providing the passage cross section of the second magnetic foreign matter capturing passage in a gradually deformed shape that shifts from a narrow gap to a wide gap, the second magnetic foreign matter catching passage is reliably caught and the second magnetic foreign matter catching passage is attracted by the adsorbed magnetic foreign matter. It is possible to achieve both the prevention of clogging of the foreign matter capturing passage.

[Means of claim 5]
The OCV adopting the means of claim 5 is used in a hydraulic circuit, and the hydraulic circuit is combined with a variable valve timing mechanism (hereinafter referred to as VCT) and is generated at a hydraulic source during operation of the internal combustion engine. The hydraulic pressure is supplied and discharged relative to the advance chamber and the retard chamber.
Since the OCV has an excellent effect as described above, the reliability of the VVT configured by the hydraulic circuit using the OCV and the VCT can be improved.

The OCV of the best mode 1 includes an electromagnetic actuator including a coil, a plunger and a stator, a spool valve including a sleeve and a spool, a shaft for interlocking the plunger and the spool, and one of the plunger and the spool (what is the magnetic attraction direction of the plunger? Biasing means for biasing to a different side.
The electromagnetic actuator includes first and second volume fluctuation chambers on both axial sides of the plunger. The sleeve includes a breathing hole that communicates with the external oil passage.
The plunger is a combination of the first and second plungers through which the magnetic field lines generated by the coil pass.
The first volume fluctuation chamber and the breathing hole on the stator side that performs magnetic attraction are formed by a gap between the first and second plungers, and communicate with each other via a first magnetic foreign material capturing passage through which the magnetic field lines cross.

The OCV plunger of the best mode 2 is a combination of the OCV of the best mode 1 and a third plunger, and a gap between the first and third plungers or a gap between the second and third plungers. The at least one gap forms a second magnetic foreign material capturing passage through which the magnetic lines of force traverse.
The second volume fluctuation chamber and the breathing hole communicate with each other through the second magnetic foreign substance capturing passage.

  The plunger of the OCV of the best mode 3 is such that the cross section of at least one of the first magnetic foreign material trapping path or the second magnetic foreign material trapping path in the best mode 1 or the best mode 2 is changed from a narrow gap to a wide gap. It is provided in a gradually deforming shape that shifts.

A first embodiment will be described with reference to FIGS.
First, VVT will be described with reference to FIG.
The VVT shown in the first embodiment is attached to a camshaft (either an intake valve, an exhaust valve, or an intake / exhaust camshaft) of an internal combustion engine (hereinafter referred to as an engine). Can be varied.
The VVT includes a hydraulic circuit 3 having a VCT1, an OCV2, and an ECU 4 (control device) that controls the OCV2.

(Description of VCT1)
The VCT 1 is a shoe housing 5 (corresponding to a rotational drive body) that is rotationally driven in synchronization with the crankshaft of the engine, and a vane rotor that is provided so as to be relatively rotatable with respect to the shoe housing 5 and rotates integrally with the camshaft. 6 (corresponding to a rotating follower), and the vane rotor 6 is driven to rotate relative to the shoe housing 5 by a hydraulic actuator configured in the shoe housing 5 so that the camshaft is advanced. Alternatively, it is changed to the retard side.

The shoe housing 5 is coupled to a sprocket that is rotationally driven by a crankshaft of an engine via a timing belt, a timing chain, or the like by a bolt or the like, and rotates integrally with the sprocket. As shown in FIG. 3, a plurality of substantially fan-shaped recesses 7 (three in this embodiment) are formed in the shoe housing 5. In addition, the shoe housing 5 rotates clockwise in FIG. 3, and this rotation direction is an advance angle direction.
On the other hand, the vane rotor 6 is positioned at the end of the camshaft by a positioning pin or the like and fixed to the end of the camshaft by a bolt or the like, and rotates integrally with the camshaft.

The vane rotor 6 includes a vane 6a that divides the recess 7 of the shoe housing 5 into an advance chamber 7a and a retard chamber 7b. The vane rotor 6 is provided so as to be rotatable within a predetermined angle with respect to the shoe housing 5. It has been.
The advance chamber 7a is a hydraulic chamber for driving the vane 6a to the advance side by hydraulic pressure, and is formed in the recess 7 on the side opposite to the rotation direction of the vane 6a. Is a hydraulic chamber for driving the vane 6a to the retard side by hydraulic pressure. In addition, the liquid tightness in each chamber 7a, 7b is maintained by the sealing member 8 grade | etc.,.

(Description of hydraulic circuit 3)
The hydraulic circuit 3 supplies and discharges oil to and from the advance chamber 7a and the retard chamber 7b, generates a hydraulic pressure difference between the advance chamber 7a and the retard chamber 7b, and rotates the vane rotor 6 relative to the shoe housing 5. And an oil pump 9 driven by a crankshaft or the like, and an OCV 2 that switches and supplies oil (hydraulic pressure) pumped by the oil pump 9 to the advance chamber 7a or the retard chamber 7b.

The OCV 2 will be described with reference to FIG.
The OCV 2 includes a spool valve 10 including a sleeve 11 and a spool 12, and an electromagnetic actuator 13 that drives the spool 12 in the axial direction.
The sleeve 11 has a substantially cylindrical shape, and has a plurality of input / output ports. Specifically, the sleeve 11 of the first embodiment communicates with an insertion hole 11a that supports the spool 12 so as to be slidable in the axial direction, a hydraulic pressure supply port 11b that communicates with the oil discharge port of the oil pump 9, and an advance chamber 7a. An advance chamber communication port 11c, a retard chamber communication port 11d communicating with the retard chamber 7b, and a drain port 11e for returning oil into the oil pan 9a are formed.

  The hydraulic pressure supply port 11b, the advance chamber communication port 11c, and the retard chamber communication port 11d are holes formed in the side surface of the sleeve 11, from the left side (counter coil side) to the right side (coil side) in FIG. A drain port 11e, an advance chamber communication port 11c, a hydraulic pressure supply port 11b, a retard chamber communication port 11d, and a drain port 11e are formed.

The spool 12 includes four large-diameter portions 12a (land) for blocking a port having an outer diameter that substantially matches the inner diameter of the sleeve 11 (the diameter of the insertion hole 11a).
Between each large-diameter portion 12a, the advance chamber drain small-diameter portion 12b for changing the communication state of the plurality of input / output ports (11b to 11e) according to the axial position of the spool 12, and the small-diameter portion 12c for hydraulic pressure supply A small-diameter portion 12d for retarded angle chamber drain is formed.
The advanced chamber drain small diameter portion 12b is for draining the hydraulic pressure of the advance chamber 7a when the hydraulic pressure is supplied to the retard chamber 7b, and the hydraulic supply small diameter portion 12c is the advance chamber 7a or the retard chamber. The retarded chamber drain small-diameter portion 12d is for draining the hydraulic pressure of the retarded chamber 7b when the hydraulic pressure is supplied to the advanced chamber 7a. is there.

The electromagnetic actuator 13 includes a plunger 15, a stator 16, a coil 17, a yoke 18, and a connector 19.
The plunger 15 is formed of a magnetic metal (for example, iron: a ferromagnetic material constituting a magnetic circuit) that is magnetically attracted to the stator 16, and is disposed inside the stator 16 (specifically, for oil seals). The inner side of the cup guide 20) is supported so as to be slidable in the axial direction.

The stator 16 is made of a magnetic metal (for example, a metal part 16a that is disposed between the sleeve 11 and the coil 17 and a cylindrical part 16b that guides the magnetic flux of the disk part 16a to the vicinity of the plunger 15. Iron: a ferromagnetic material constituting a magnetic circuit), and a magnetic attraction gap MG (main gap) is formed between the plunger 15 and the cylindrical portion 16b.
A concave portion 16c is formed at the end portion of the cylindrical portion 16b so that the end portion of the plunger 15 is not contacted, and the plunger 15 and a part of the stator 16 are provided so as to intersect in the axial direction. Note that a taper 16 d is formed at the end of the cylindrical portion 16 b, so that the magnetic attractive force does not change with respect to the stroke amount of the plunger 15.

The coil 17 is a magnetic force generating means that generates a magnetic force when energized and magnetically attracts the plunger 15 to the stator 16, and is formed by winding a number of enamel wires around a resin bobbin 17a.
The yoke 18 is a magnetic metal (for example, iron: a ferromagnetic material constituting a magnetic circuit) provided with an inner cylindrical portion 18a that covers the periphery of the plunger 15 and an outer cylindrical portion 18b that covers the periphery of the coil 17, and the left side of FIG. The sleeve 11 is joined by caulking the claw portion formed on the sleeve. The inner cylinder part 18a performs magnetic flux delivery with the plunger 15, and a magnetic flux delivery gap SG (side gap) is formed between the plunger 15 and the inner cylinder part 18a.
The connector 19 is a connection means for making an electrical connection with the ECU 4 via a connection line, and terminals 19 a respectively connected to both ends of the coil 17 are disposed therein.

  In addition, the OCV 2 transmits the movement of the plunger 15 to the left side in FIG. 4 to the spool 12, and transmits the movement of the spool 12 to the right side in FIG. 4 to the plunger 15. A spring 22 (corresponding to a biasing means) that biases the spool 12 and the plunger 15 is provided on the right side of FIG.

The shaft 21 is supported so as to be slidable in the axial direction by an inner peripheral surface of a cylindrical collar 23 disposed inside the disk portion 16a of the stator 16, and one end abuts against the spool 12. The other end contacts the plunger 15.
In the first embodiment, the shaft 21 and the spool 12 are in contact with each other. However, the shaft 21 and the spool 12 may be fixed by press-fitting or the like. Moreover, although the example which the shaft 21 and the plunger 15 contact | abut is shown, you may fix the shaft 21 and the plunger 15 by press injection etc. FIG. In that case, you may utilize the part inserted and fixed to the plunger 15 as a 2nd plunger or a 3rd plunger mentioned later.

  The spring 22 is arranged at the end of the spool 12 on the side opposite to the coil (left side in FIG. 4) and urges the spool 12 to the right side in FIG. 4, but the spool 12 and the plunger 15 are fixed to the shaft 21. In some cases, the spring 22 may be disposed at another position, for example, between the stator 16 and the plunger 15 to urge the plunger 15 to the right in FIG.

In the OCV 2, when the coil 17 is OFF, the spool 12 and the plunger 15 are displaced to the coil side (right side in FIG. 4) by the urging force of the spring 22 and stopped.
In this stopped state, the maximum gap of the magnetic attraction gap MG is determined, and the spool 12 is positioned with respect to the sleeve 11.
In addition, the code | symbol 24 shown in FIG. 4 is an O-ring for sealing.

(Description of ECU 4)
The ECU 4 controls the amount of current supplied to the coil 17 of the electromagnetic actuator 13 (hereinafter referred to as supply current amount) by duty ratio control. By controlling the amount of supply current to the coil 17, the axial direction of the spool 12 is controlled. Is controlled linearly, and hydraulic pressure is generated in the advance chamber 7a and the retard chamber 7b in accordance with the operating state of the engine to control the advance phase of the camshaft.

(Explanation of VVT operation)
When the ECU 4 advances the camshaft according to the driving state of the vehicle, the ECU 4 increases the amount of current supplied to the coil 17. Then, the magnetic force generated by the coil 17 increases, and the plunger 15 and the spool 12 move to the non-coil side (left side in FIG. 4: advance side). Then, the communication ratio between the hydraulic pressure supply port 11b and the advance chamber communication port 11c increases, and the communication ratio between the retard chamber communication port 11d and the drain port 11e increases. As a result, the hydraulic pressure of the advance chamber 7a increases, and conversely, the hydraulic pressure of the retard chamber 7b decreases, the vane rotor 6 is displaced toward the advance side relative to the shoe housing 5, and the camshaft is advanced. To do.

  Conversely, when the ECU 4 retards the camshaft according to the driving state of the vehicle, the ECU 4 decreases the amount of current supplied to the coil 17. Then, the magnetic force generated by the coil 17 decreases, and the plunger 15 and the spool 12 move to the coil side (right side in FIG. 4: retarded side). Then, the communication ratio between the hydraulic pressure supply port 11b and the retard chamber communication port 11d increases, and the communication ratio between the advance chamber communication port 11c and the drain port 11e increases. As a result, the hydraulic pressure in the retard chamber 7b increases, and conversely, the hydraulic pressure in the advance chamber 7a decreases, the vane rotor 6 is displaced relative to the shoe housing 5 toward the retard side, and the camshaft is retarded. To do.

[Features of Example 1]
Since the plunger 15 moves in the axial direction inside the electromagnetic actuator 13, a volume fluctuation chamber in which the volume fluctuates with the movement of the plunger 15 is formed on both sides of the plunger 15 in the axial direction.
The volume fluctuation chamber on the stator side (left side in FIG. 4) of the plunger 15 is referred to as a first volume fluctuation chamber A, and the volume fluctuation chamber on the non-stator side of the plunger 15 (side different from the first volume fluctuation chamber A: right side in FIG. 4). Is referred to as a second volume fluctuation chamber B.

On the other hand, since the spool 12 also moves in the axial direction inside the sleeve 11, a volume fluctuation chamber in which the volume fluctuates with the movement of the spool 12 is formed on both sides of the sleeve 11 in the axial direction.
The volume fluctuation chamber on the electromagnetic actuator side (right side in FIG. 4) of the spool 12 is referred to as a third volume fluctuation chamber C, and the volume fluctuation chamber on the anti-electromagnetic actuator side (left side in FIG. 4) of the spool 12 is referred to as a fourth volume fluctuation chamber D. .

The sleeve 11 is formed with a first breathing hole 11 f communicating with the third volume variation chamber C and a second breathing hole 11 g communicating with the fourth volume variation chamber D.
The first and second breathing holes 11f and 11g are oil passages communicating with an external oil passage (oil passage leading to the drain port 11e) for returning oil to the oil pan 9a. When the spool 12 is displaced in the axial direction, The oil in the third and fourth volume fluctuation chambers C and D is supplied and discharged from the first and second breathing holes 11f and 11g, respectively.

  The second volume fluctuation chamber B communicates with the third volume fluctuation chamber C via the in-plunger breathing path 15 a formed in the center of the plunger 15 and the in-shaft breathing path 21 a formed in the center of the shaft 21. The oil in the second volume fluctuation chamber B is supplied and discharged through the plunger breathing path 15a → the shaft breathing path 21a → the third volume fluctuation chamber C → the first breathing hole 11f. In the first embodiment, an example is shown in which the breathing groove 12e is formed on the surface of the spool 12 on which the shaft 21 abuts, thereby communicating the third volume fluctuation chamber C with the in-shaft breathing path 21a. The third volume fluctuation chamber C and the in-shaft breathing path 21a may be communicated with each other by other means such as forming a breathing groove on the surface where the spool 12 abuts.

Next, a breathing passage for supplying and discharging oil to the first volume fluctuation chamber A will be described with reference to FIGS.
The first volume fluctuation chamber A communicates with the in-plunger breathing path 15a through a first magnetic foreign substance capturing passage 15α formed in the plunger 15, and the oil in the first volume fluctuation chamber A is the first magnetic It is supplied / exhausted through the foreign matter trapping passage 15α → the respiration passage in the plunger 15a → the respiration passage in the shaft 21a → the third volume fluctuation chamber C → the first respiration hole 11f (see FIG. 4). That is, the first volume fluctuation chamber A and the first breathing hole 11f (see FIG. 4) communicate with each other via the first magnetic foreign matter capturing passage 15α.

The first magnetic foreign matter capturing passage 15α will be described.
The plunger 15 is a combination of two members (first and second plungers α and β) on the magnetic attraction gap MG side, and the magnetic field lines generated by the coil 17 are those of the first and second plungers α and β. A magnetic field line is provided so as to pass through each of the first and second plungers α and β across the gap.
On the dividing surface (combination surface) of the first and second plungers α and β, there is provided a gap that communicates the first volume variation chamber A and the in-plunger breathing path 15a, and the first magnetic foreign substance capturing passage 15α is formed by the gap. It is formed.
And this 1st magnetic foreign material capture | acquisition channel | path 15 (alpha) is provided in the slow deformation shape from which a channel | path cross section transfers to a wide clearance gap from a narrow clearance gap.

The first magnetic foreign matter capturing passage 15α in the first embodiment will be described.
As shown in FIGS. 2A and 2B, the first plunger α constituting the main part of the plunger 15 has an octagonal inner peripheral surface that is recessed in the axial direction at the center on the side where the shaft 21 abuts. An octagonal recess α1 is formed, and on the bottom surface in the axial direction of the octagonal recess α1, as shown in FIG. 2B, a gap is formed in the axial direction of the first plunger α and the second plunger β. A bottom recess α2 is formed. Note that the hatching shown in the bottom surface recess α2 in FIG. 2B is for facilitating the distinction from the bottom surface recess α2 of the adjacent portion.
The second plunger β has a cylindrical shape that is lightly press-fitted into the octagonal recess α1 of the first plunger α. The second plunger β has a circular inner surface and an outer peripheral surface. The reason why the second plunger β is lightly press-fitted into the octagonal recess α1 is to improve the assemblability, and it is sufficient that the second plunger β can be inserted into the octagonal recess α1, for example, the second plunger β is inserted into the octagonal recess α1. It may be loosely fitted.
Then, by inserting the second plunger β inside the octagonal recess α1, the first volume fluctuation chamber A and the in-plunger breathing path 15a are communicated with the gap between the first plunger α and the second plunger β, and Eight first magnetic foreign matter trapping passages 15α whose passage section is gradually deformed are formed.

[Effect of Example 1]
The oil supplied to and discharged from the first volume fluctuation chamber A is supplied and discharged through the first magnetic foreign matter capturing passage 15α through which the magnetic lines of force generated by the coil 17 cross. For this reason, the magnetic foreign matter contained in the oil is captured by the magnetic force generated in the first magnetic foreign matter capturing passage 15α, and the magnetic foreign matter does not enter the first volume fluctuation chamber A in which the magnetic attraction gap MG is formed.
As a result, the magnetic flux generated by the magnetic foreign substance entering the first volume fluctuation chamber A is not unbalanced, and the side force is generated in the plunger 15 due to the unbalanced magnetic flux. The problem that the sliding resistance increases due to rubbing against the portion is not generated, and the smooth movement of the plunger 15 can be maintained over a long period of time.
Of course, since a diaphragm as shown in the prior art is not used, there is no problem that the movement of the plunger 15 is obstructed by the diaphragm, and there is no problem that the life of the OCV 2 is shortened due to the fatigue of the diaphragm.

Moreover, OCV2 of Example 1 provided the passage cross section of the 1st magnetic foreign material capture | acquisition passage 15 (alpha) in the slow deformation shape which transfers to a wide clearance gap from a narrow clearance gap.
Since the magnetic force becomes strong in the narrow gap, the magnetic foreign matter mixed in the oil can be reliably caught by the strong magnetic force. As the accumulation of foreign matter progresses, the magnetic foreign matter deposit site moves to a wide gap thereafter. Thereby, a magnetic foreign material can be captured stably for a long time.
Further, since the wide gap can secure a space for oil to flow at least in the central portion of the wide gap even when the magnetic foreign matter is adsorbed by a magnetic force in the surroundings, the magnetic foreign matter caught in the first magnetic foreign matter catching passage 15α. Therefore, there is no problem that the first magnetic foreign matter capturing passage 15α is clogged.
Thus, by providing the passage cross section of the first magnetic foreign matter capturing passage 15α in a gradually deformed shape that shifts from a narrow gap to a wide gap, the magnetic foreign matter contained in the oil can be reliably secured by the first magnetic foreign matter catching passage 15α. It is possible to achieve both of capturing and preventing the first magnetic foreign material capturing passage 15α from being clogged by the magnetic foreign material captured in the first magnetic foreign material capturing passage 15α.

  Furthermore, since the OCV 2 of the first embodiment can avoid the sliding failure of the plunger 15 caused by the entry of the magnetic foreign matter into the first volume fluctuation chamber A where the magnetic attraction gap MG is formed, it can be avoided for a long time. As described above, the reliability of the VVT including the hydraulic circuit 3 using the excellent OCV 2 and the VCT 1 can be improved.

A second embodiment will be described with reference to FIGS. In addition, the same code | symbol as Example 1 shows the same functional thing.
The second volume fluctuation chamber B of the first embodiment communicates with the in-shaft breathing passage 21a in the shaft 21 via the in-plunger breathing passage 15a formed in the center of the plunger 15 and having a relatively large passage section. Indicated.
On the other hand, in the second embodiment, in addition to the configuration of the OCV 2 of the first embodiment, both the first and second plungers α and β are placed inside the plunger breathing passage 15a on the side close to the magnetic attraction gap MG. A third plunger γ to be inserted into the interior is assembled, and a second magnetic foreign substance that communicates with the second volume variation chamber B in the gap between the first plunger α and the third plunger γ and the gap between the second plunger β and the third plunger γ, respectively. A capture passage 15β was formed. That is, the second volume fluctuation chamber B communicates with the in-shaft breathing path 21a via the second magnetic foreign matter capturing path 15β.

The second magnetic foreign matter capturing passage 15β will be described.
The plunger 15 is a combination of three members (first to third plungers α to γ) on the magnetic attraction gap MG side, and the magnetic lines of force generated by the coil 17 are those of the first to third plungers α to γ. A magnetic field line passes through each gap and passes through each of the first to third plungers α to γ.
The second volume fluctuation chamber B and the in-shaft respiratory path 21a are provided on the dividing surfaces (combination surfaces) of the first and third plungers α and γ and the dividing surfaces (combination surfaces) of the second and third plungers β and γ. A communicating gap is provided, and the second magnetic foreign matter capturing passage 15β is formed by the gap.
And this 2nd magnetic foreign material capture | acquisition channel | path 15 (beta) is provided in the gradual deformation form which a passage cross section changes to a wide clearance gap like the 1st magnetic foreign material capture | acquisition passage 15 (alpha).

The second magnetic foreign matter trapping passage 15β in the second embodiment will be described.
As shown in FIG. 6, the third plunger γ is a hexagonal column whose outer peripheral shape is inserted into both the first and second plungers α and β, and the first plunger α or the second plunger β is small. Is also press-fitted to one side.
The third plunger γ is inserted into both the first and second plungers α and β, so that the gap between the first plunger α and the third plunger γ, and the second plunger β and the third plunger γ. Are formed with six second magnetic foreign matter capturing passages 15β whose passage section is gradually deformed.

[Effect of Example 2]
The oil supplied to and discharged from the second volume fluctuation chamber B is supplied and discharged through the second magnetic foreign material capturing passage 15β traversed by the magnetic field lines generated by the coil 17. For this reason, the magnetic foreign matter contained in the oil is captured by the magnetic force generated in the second magnetic foreign matter capturing passage 15β, and the magnetic foreign matter does not enter the second volume fluctuation chamber B.
As a result, it is possible to prevent the sliding failure that occurs when the magnetic foreign matter enters the second volume fluctuation chamber B, and it is possible to maintain the smooth movement of the plunger 15 over a long period of time.

Further, in the OCV 2 of Example 2, the passage cross section of the second magnetic foreign matter trapping passage 15β is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap, like the passage cross section of the first magnetic foreign matter trapping passage 15α.
Since the magnetic force becomes strong in the narrow gap, the magnetic foreign matter mixed in the oil can be reliably caught by the strong magnetic force. As the accumulation of foreign matter progresses, the magnetic foreign matter deposit site moves to a wide gap thereafter. Thereby, a magnetic foreign material can be captured stably for a long time.
Further, since the wide gap can secure a space for oil to flow at least in the central portion of the wide gap even when the magnetic foreign matter is adsorbed by a magnetic force in the surroundings, the magnetic foreign matter caught in the second magnetic foreign matter catching passage 15β is secured. Therefore, there is no problem that the second magnetic foreign matter capturing passage 15β is clogged.
As described above, the passage cross section of the second magnetic foreign matter capturing passage 15β is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap, so that the magnetic foreign matter contained in the oil can be reliably caught and the adsorbed magnetic It is possible to achieve both the prevention of the second magnetic foreign matter capturing passage 15β from being clogged with foreign matters.

  Further, the first magnetic foreign matter catching passage 15α of the second embodiment communicates with the gap between the second and third plungers β and γ, and communicates with the intermediate portion of the second magnetic foreign matter catching passage 15β. For this reason, since the magnetic foreign matter contained in the oil flowing into the first magnetic foreign matter catching passage 15α is caught by the second magnetic foreign matter catching passage 15β, the possibility of the magnetic foreign matter entering the first volume fluctuation chamber A is implemented. Compared to Example 1, it can be further reduced, and the long-term reliability of the OCV 2 can be further increased.

[Modification]
The VCT 1 shown in the above embodiment is an example for explaining the embodiment, and may be another structure as long as the advance angle can be adjusted by a hydraulic actuator inside the VCT 1.
For example, in the above embodiment, an example in which three recesses 7 are formed in the shoe housing 5 and three vanes 6a are provided on the outer peripheral portion of the vane rotor 6 is shown. Any number of the concave portions 7 and the vanes 6a may be used as long as the number of the concave portions 7 and the vanes 6a is one or more.
Moreover, although the shoe housing 5 rotates synchronously with the crankshaft and the vane rotor 6 rotates integrally with the camshaft, the vane rotor 6 rotates synchronously with the crankshaft so that the shoe housing 5 rotates integrally with the camshaft. It may be configured.

In the above-described embodiment, an example in which the spool 12 having the large diameter portion 12a and the small diameter portions 12b to 12d is used has been described. However, the structure of the spool 12 is not limited, and for example, a cylindrical spool is used. Also good.
In the above embodiment, an example is shown in which holes are formed in the side surface of the sleeve 11 to provide input / output ports (in the embodiment, the hydraulic pressure supply port 11b, the advance chamber communication port 11c, the retard chamber communication port 11d, etc.). However, the structure of the sleeve 11 is not limited. For example, a plurality of input / output ports may be formed by forming through holes in the diameter direction of the sleeve 11.

The structure of the electromagnetic actuator 13 shown in the above embodiment is an example for explaining the embodiment, and may be another structure. For example, the plunger 15 may be disposed in the axial direction of the coil 17.
In the above embodiment, the spool 12 is displaced toward the non-coil side when the coil 17 is turned on. Conversely, the spool 12 may be displaced toward the coil side when the coil 17 is turned on.

In the above-described embodiment, the inner circumferential surface of the recess into which the second plunger β is inserted in the first plunger α is provided in an octagon (octagonal recess α1), so that the passage cross section of the first magnetic foreign matter capturing passage 15α is gradually deformed. Although the example described above is shown, the passage cross section of the first magnetic foreign matter capturing passage 15α may be gradually deformed by using a shape (polygon) other than the octagon.
In addition, the inner circumference of the recess into which the second plunger β is inserted in the first plunger α is provided in a cylinder, and the outer circumference of the second plunger β is provided in a polygon such as an octagon, whereby the first magnetic foreign matter capturing passage 15α is obtained. The passage cross section may be gradually deformed.

In the above embodiment, the example in which the outer diameter shape of the third plunger γ is provided in a hexagonal shape so that the passage cross section of the second magnetic foreign matter capturing passage 15β is gradually deformed is shown. The passage cross section of the second magnetic foreign material capturing passage 15β may be gradually deformed by making the shape (polygon).
In addition, the outer periphery of the third plunger γ is provided in a circle, and the shape of the inner periphery (the inner peripheral surface of the first and second plungers α and β) of the plunger inner respiratory passage 15a into which the third plunger γ is inserted is a hexagonal shape. By providing in a polygonal shape, the passage cross section of the second magnetic foreign matter capturing passage 15β may be gradually deformed.

An in-spool breathing path that communicates with a breathing hole formed in the sleeve 11 may be formed in the spool 12, and the in-spool breathing path and the in-shaft breathing path 21a may be communicated with each other.
In the above embodiment, the present invention is applied to the OCV 2 combined with the VCT 1. However, the present invention is applied to all OCVs that switch the oil flow and the oil flow direction, such as an OCV used in a hydraulic control device of an automatic transmission. It is possible.

(Example 1) which is sectional drawing which follows the axial direction of the electromagnetic actuator in OCV. It is sectional drawing of the plunger which follows the II line | wire of FIG. 1, and the figure which looked at the plunger from the axial direction (magnetic attraction side) (Example 1). It is the schematic of VVT (Example 1). It is sectional drawing which follows the axial direction of OCV (Example 1). (Example 2) which is sectional drawing which follows the axial direction of the electromagnetic actuator in OCV. (Example 2) which is sectional drawing of the plunger which follows the II-II line | wire of FIG.

Explanation of symbols

1 VCT (Variable valve timing mechanism)
2 OCV (oil flow control valve)
5 Shoe handling (rotary drive)
6 Vane rotor (rotating follower)
7a Lead angle chamber 7b Delay angle chamber 10 Spool valve 11 Sleeve 11b Hydraulic supply port (input / output port)
11c Leading angle communication port (input / output port)
11d retarded room communication port (input / output port)
11e Drain port (I / O port)
11f 1st breathing hole (breathing hole connected with the 1st, 2nd volume fluctuation chamber)
12 Spool 13 Electromagnetic Actuator 15 Plunger 15α First Magnetic Foreign Object Capture Passage 15β Second Magnetic Foreign Object Capture Passage 16 Stator 17 Coil 21 Shaft 22 Spring (Biasing Means)
A 1st volume fluctuation chamber B 2nd volume fluctuation chamber α 1st plunger β 2nd plunger γ 3rd plunger

Claims (5)

(A) a sleeve in which an input / output port for oil is formed, a spool valve having a spool for switching the input / output port by being displaced in the axial direction inside the sleeve;
(B) a coil that generates a magnetic force when energized, a plunger that is movable in the axial direction, and a stator that guides the magnetic force generated by the coil to an opposing position in the axial direction of the plunger, and the magnetic force generated by the coil An electromagnetic actuator for attracting the plunger to the stator;
(C) a shaft for transmitting the movement of the plunger in the axial direction to the spool and for transmitting the movement of the spool in the axial direction to the plunger;
(D) urging means for urging the plunger and the spool in a direction in which the facing distance between the plunger and the stator is increased;
(E) The electromagnetic actuator is
A first volume variation chamber in an axial direction of the plunger facing the stator;
The plunger includes a second volume variation chamber in an axial direction on a side different from the first volume variation chamber;
(F) the sleeve has a breathing hole communicating with an external oil passage;
(G) The plunger is a combination of first and second plungers through which the lines of magnetic force generated by the coil pass.
(H) The oil flow characterized in that the first volume fluctuation chamber and the breathing hole are formed by a gap between the first and second plungers and communicate with each other through a first magnetic foreign substance capturing passage through which a magnetic field line crosses. Control valve. In the oil flow control valve according to claim 1,
The oil flow control valve according to claim 1, wherein a passage cross section of the first magnetic foreign matter capturing passage is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap. In the oil flow control valve according to claim 1 or 2,
The plunger is a combination of first to third plungers through which the lines of magnetic force generated by the coil pass,
The second volume fluctuation chamber and the breathing hole are formed by at least one of the gap between the first and third plungers or the gap between the second and third plungers, and a second magnetic foreign matter trapping path through which the lines of magnetic force cross. Oil flow control valve characterized by communicating through In the oil flow control valve according to claim 3,
The oil flow control valve according to claim 1, wherein a passage section of the second magnetic foreign matter trapping passage is provided in a gradually deformed shape that shifts from a narrow gap to a wide gap. In the oil flow control valve according to any one of claims 1 to 4,
This oil flow control valve
A rotationally driven body that is rotationally driven in synchronization with the crankshaft of the internal combustion engine;
A rotation follower that is provided so as to be relatively rotatable with respect to the rotary drive body, and that rotates integrally with the camshaft of the internal combustion engine;
By supplying hydraulic pressure to an advance angle chamber formed between the rotation drive body and the rotation follower, the camshaft is displaced together with the rotation follower to the advance angle side with respect to the rotation drive body, and Valve timing for displacing the camshaft together with the rotary follower to the retard side by supplying hydraulic pressure to a retard chamber formed between the rotary drive and the rotary follower. Combined with variable mechanism,
An oil flow control valve characterized in that during operation of the internal combustion engine, hydraulic pressure generated by a hydraulic pressure source is relatively supplied to and discharged from the advance chamber and the retard chamber.

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