The disclosure of Japanese Patent Application No. 2010-024870 filed on Feb. 5, 2010 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
The present invention relates to an oil pump installed in an automatic transmission or the like, for example. More specifically, the present invention relates to an oil pump that suctions and discharges hydraulic oil by meshing external teeth of an inner rotor with internal teeth of an eccentrically-formed outer rotor, and increasing and decreasing a space between the inner rotor and the outer rotor.
In general, inscribed oil pumps as typified by a trochoid oil pump, for example, are widely known as oil pumps used in vehicles such as automobiles.
Inscribed oil pumps are configured by meshing external teeth of an inner rotor with internal teeth of an eccentric outer rotor. Rotational driving of the inner rotor causes a space between the inner and outer rotors to increase along an intake port to suction hydraulic oil, and decrease toward a discharge port so as to discharge the suctioned hydraulic oil.
In this type of oil pump, when the rotor rotates at high speed, a negative pressure on the intake port side of the space becomes partially lower than a saturated vapor pressure of the hydraulic oil. As a consequence, the hydraulic oil vaporizes and causes cavitation (air bubbles) in the space.
When cavitation occurs, the liquid hydraulic oil becomes a gas whose volume sharply increases. In addition to the risk of the oil pump discharge amount becoming insufficient, the space communicates with the discharge port and an internal pressure of the space becomes equal to or greater than the saturated vapor pressure of the hydraulic oil, which eliminates a cavitation at a specific location but also generates a jet stream that causes erosion in the oil pump.
When a cavitation disappears, surrounding hydraulic oil rushes toward the center of the air bubble and the subsequent collision of hydraulic oil generates a pressure wave. This pressure wave becomes cavitation noise, and increases noise and vibration in the oil pump.
In order to suppress such erosion and cavitation noise, related art proposes an oil pump in which a pressure reducing shallow groove D for supplying hydraulic oil from a delivery port 5 is formed in a space part (gap part) S at the time of a maximum volume Vmax (see Japanese Patent No. 2582167).
The oil pump of Japanese Patent No. 2582167 is effective against erosion because hydraulic oil flows from the delivery port into the space part through the pressure reducing shallow groove at the time of the maximum volume to increase the internal pressure of the space part, which reduces the difference between a discharge pressure and the internal pressure of the space part, and also reduces the momentum of the jet stream.
However, it is difficult to gradually increase the internal pressure of the space part with the above-described method of using hydraulic oil from the delivery port to increase the pressure of the space part, and at the stage of communication with the delivery port a certain amount of cavitation remains within the space part.
Such remaining cavitation is collectively eliminated as soon as the space part communicates with the delivery port. A loud cavitation noise is still generated as a consequence, so such a mechanism for reducing oil pump noise is still inadequate.
The present invention provides an oil pump that solves the above problem by providing a compression stroke between an intake stroke that suctions hydraulic oil and a discharge stroke that discharges hydraulic oil, and gradually smashing and eliminating cavitation in the compression stroke.
According to a first aspect of the present invention, a compression stroke that compresses an inter-rotor space is provided between an intake stroke and a discharge stroke. A rotation angle that an inner rotor advances during the compression stroke is set within a range of 21 to 27 degrees. Most cavitation occurring in the space can thus be gradually smashed and eliminated during the compression stroke, and oil pump noise can be kept within a range that does not cause the driver to feel discomfort. In addition, such cavitation disperses and disappears over time during the compression stroke instead of collectively disappearing at a specific site, which can help prevent the occurrence of erosion.
According to a second aspect of the present invention, at low revolution where cavitation does not occur, hydraulic oil compressed in the compression stroke can be discharged to a discharge port through a shallow groove. Therefore, an excessive increase in the pressure of the space during the compression stroke can be suppressed. In addition, noise at a meshing portion of the inner rotor and an outer rotor, as well as a decrease in fuel economy from the excessive increase in the internal pressure of the space can also be suppressed.
An oil pump according to embodiments of the present invention will be described below with reference to the drawings. An oil pump 1 is provided between a speed change mechanism (not shown) constituted from a plurality of planetary gears and a torque converter (not shown) of an automatic transmission. As shown in
A sliding surface 5a of the oil pump body 5 that slides against the inner rotor 3 and the outer rotor 2 is formed with an intake port 11 that communicates with an oil pan via a strainer, and a discharge port 10 that communicates with a control valve of the automatic transmission. The intake port 11 and the discharge port 10 oppose each other. In addition, the inner rotor 3 is fixedly attached through a key 3b and a key groove 6a to an oil pump drive shaft 6 that connects to an output shaft of a drive source.
The outer rotor 2 is eccentrically provided. Therefore, a space S formed between one pitch of the external teeth 3a and the internal teeth 2a has a volume that increases and decreases in accordance with the rotation of the inner rotor 3 and the outer rotor 2, when the inner rotor 3 is rotationally driven from an intake port 11 side to a discharge port 10 side (a rotation direction R in
Specifically, the space S is formed between an engagement point E1 on a rotation forward side and an engagement point E2 on a rotation rearward side of the external teeth 3a and the internal teeth 2a. As shown by a space S1 in
As evident from
As shown by a space S2 in
Between the finish end portion 11b of the intake port 11 and a start end portion 10a of the discharge port 10, a predetermined interval (angle) c is formed by an inter-port partition portion 4 that will be described in more detail later, and the inter-port partition portion 4 is configured so as to delay a discharge timing at which the engagement point E1 on the rotation forward side communicates with the discharge port 10. Therefore, the volume of the space S, as shown by a space S3 in
Once the engagement point E1 on the rotation forward side arrives at the start end portion 10a of the discharge port 10, as shown by a space S4 in
Note that the finish end portion 11b of the intake port 11 is formed with a recess portion at a radial position on a locus 1 formed by the engagement points E1, E2 so that more hydraulic oil can be suctioned into the space S, and a peak in the recess portion is the finish end portion 11b of the intake port 11 (see
Next, the port configuration of the oil pump 1 will be described. As mentioned above, the inter-port partition portion 4 provides a predetermined interval c between the finish end portion 11b of the intake port 11 and the start end portion 10a of the discharge port 11. The confinement stroke II and the compression stroke III occur within the predetermined interval c.
As shown in
Also, within the inter-port partition portion 4, the compression stroke III occurs between the engagement point E1 on the rotation forward side during the confinement stroke II and the start end portion 10a of the discharge port 10. In other words, referring to
Further, spanning the compression angle a, the sliding surface 5a of the oil pump body 5 is provided with a shallow groove 12 that communicates with the space S3 and the start end portion 10a of the discharge port 10 during the compression stroke. The shallow groove 12 is positioned on the locus 1 formed by the engagement points E1, E2.
Note that, in the inter-port partition portion 4, the shallow groove 12 is formed extremely shallow so as to follow the engagement points E1, E2 of the inner rotor 3 and the outer rotor 2. The shallow groove 12 is also formed such that the space S2 does not communicate with the intake port 11 and the discharge port 10 in the confinement stroke II. For example, with regard to the rotation angle of the inner rotor 3, a distal end portion of the shallow groove 12 is provided at a position where the rotation angle is advanced approximately 1 to 3 degrees more than 0 degrees with respect to the engagement point E1. When the drive source (inner rotor 3) rotates at low speed and there is a small flow of hydraulic oil, the shallow groove 12 acts as a groove that discharges hydraulic oil within the space S to the discharge port 10. The shallow groove 12 also ensures that when the drive source rotates at high speed and there is a large flow of hydraulic oil, hydraulic oil that may affect the internal pressure of the space S does not flow to the discharge port 10.
The relationship between the compression angle a and the internal pressure of the space at each stroke will be described based on a comparison of an oil pump in which the compression angle is set within a range of 21 to 27 degrees as shown in
In
Meanwhile, as shown in
In other words, since the existence of cavitation depends on the internal pressure of the space S, when the compression angle a is within the range of 21 to 27 degrees (
Examples at low revolution (0 to 4500 rpm) will be described based on
Meanwhile, as shown in
In light of the relationship between the compression angle a and the internal pressure of the space at each stroke as described above, the relationship between the compression angle a and cavitation noise will be described below.
Referring to a1, noise from the oil pump increases in the vicinity of 4500 rpm. This is because cavitation occurs in the space S when the drive source rotates at high speed, and cavitation noise is generated from the elimination of such cavitation.
Referring to a4, when the compression angle a is 27 degrees, although cavitation occurs at 4500 rpm, oil pump noise does not increase even over 4500 rpm and noise from the oil pump 1 is suppressed. At such time, noise from the oil pump 1 is kept at 80 dB or below.
Comparing B2 that is an average value when the compression angle a is 0 to 16 degrees and B1 that is an average value when the compression angle a is 21 to 27 degrees, B1 has a lower noise volume than B2. In actuality, the average noise for B2 is approximately 90 dB, and 80 dB or less for B1. There is a difference of approximately 10 dB in volume between B1 and B2. Based on this, when the compression angle a is within the range of 0 to 16 degrees (an ineffective compression angle C1 in
As described above, in the present embodiment, a confinement stroke II and a compression stroke III are provided between the intake stroke I and the discharge stroke IV. An interval c is set between the finish end portion 11b of the intake port 11 and the start end portion 10a of the discharge port 10, such that the compression angle a is within a range C2 that spans from an angle (e.g. 27 degrees) at which cavitation occurring at maximum revolution in a high revolution region, among revolution regions of the drive source used during normal vehicle running, disappears to an angle (e.g. 21 degrees) at which noise from the oil pump 1 falls to a predetermined volume or below. Accordingly, almost all cavitation can be gradually smashed and eliminated in the compression stroke III, and oil pump noise can be suppressed to a volume that does not generally cause the driver to feel discomfort.
Note that, when the noise from the oil pump 1 is directly measured as in
Dispersing and eliminating cavitation over time also enables a reduction in the occurrence of erosion.
Further, an upper limit of the compression angle a is set to an angle that enables the elimination of cavitation occurring at maximum revolution in a high revolution region, among revolution regions of the drive source used during normal vehicle running. Thus, the space S is not compressed by an amount that is more than the amount of cavitation, making it possible to suppress noise from a meshing portion of the external teeth 3a and the internal teeth 2a caused by the pressure of the space S increasing more than necessary, and also suppress a decrease in fuel economy caused by increased resistance.
Since the shallow groove 12 for draining pressure is provided over the compression angle a, even at low revolution, the internal pressure of the space S can be prevented from increasing more than necessary.
Note that the drive source in the present embodiment is not limited to an engine, and also includes a motor, a hybrid drive system that combines the engine and the motor, and an electric oil pump motor that rotates an oil pump independent of driving in a hybrid vehicle or an electric vehicle.
A hybrid vehicle may run in an EV mode that does not drive the engine at a low vehicle speed, and at a high vehicle speed the oil pump may reach a high driving revolution speed. Oil pump noise may become more noticeable because there is no engine noise while running in EV mode at a low vehicle speed. However, if the present invention is applied to such a hybrid vehicle, such oil pump noise can be reduced and noise caused by cavitation at a high vehicle speed can also be reduced.
A high revolution region among revolution regions of the drive source used during normal vehicle running is set lower than a maximum revolution among the revolution speeds allowed by the drive source. However, the maximum revolution among the high revolution region may be a maximum revolution among the allowed revolution speeds.
The oil pump according to the present invention is not limited to use in an automatic transmission, and may be used as an oil pump for an engine or other hydraulic device. Further, the internal teeth 2a and the external teeth 3a are not necessarily trochoidal teeth, and may have an ordinary tooth configuration, for example.
The oil pump according to the present invention can be utilized as, for example, an oil pump installed in an automatic transmission, a hybrid drive system, or the like.
Number | Date | Country | Kind |
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2010-024870 | Feb 2010 | JP | national |