JP2006275063A - Variable displacement pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent deterioration in pump efficiency by internal leakage. <P>SOLUTION: A first fluid pressure chamber 21 is arranged in one of the rocking direction of a cam ring 8, and a second fluid pressure chamber 22 is arranged in the other, and a spring 17 for energizing the cam ring is arranged on the second fluid pressure chamber side. A rotor 3 having a plurality of vanes 27 is eccentrically arranged in the cam ring. A meter ring orifice 136 is arranged in the middle of a delivery passage 135 of a pressure fluid delivered from a pump, and a control valve 123 is operated by differential pressure between the upstream side and the downstream side of this orifice. A delivery port 33 of the pressure fluid delivered from a pump room 11 is arranged in a side plate 7, and a first seal ring 172 for surrounding the periphery of a drive shaft 25 and a second seal ring 174 for surrounding a range wider than an area for arranging the delivery port on its outer peripheral side, are arranged on a back side surface of a pressure plate 160, and delivery pressure is introduced to an area between both these seal rings. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a variable displacement pump used, for example, as a hydraulic pressure supply source for an automobile power steering apparatus.

  Conventionally, as this type of variable displacement pump, for example, as disclosed in Patent Document 1, one having a configuration in which the discharge amount is controlled by increasing or decreasing the volume of a pump chamber is known. The configuration of the variable displacement pump described in this publication will be described with reference to FIGS.

  FIG. 9 is a cross-sectional view perpendicular to the drive shaft of a conventional variable displacement pump, FIG. 10 is a cross-sectional view along the axis of the drive shaft of the variable displacement pump, and FIGS. It is sectional drawing which shows a structure. In these drawings, reference numeral 2 denotes a pump body of a variable displacement pump (generally indicated by reference numeral 1), a cup-shaped front body 4 positioned on the left side of FIG. 10, and a plate-shaped rear body 5 positioned on the right side. It is made up of.

  The front body 4 has a circular recess 6 that opens on the right side of FIG. 10, and a pump component including a pressure plate 7, a cam ring 8, a rotor 3, an adapter ring 9, and the like is inserted into the recess 6. ing. A circular convex portion 5 a formed on the front surface of the rear body 5 is fitted into the opening of the front body 4, and the front body 4 and the rear body 5 are fixed by a fixing bolt 10. Four circular recesses 6 are closed. The circular protrusion 5a of the rear body 5 constitutes one side wall of a pump chamber 11 which will be described later, and pressure oil is prevented from leaking to the outside of the pump body 2 by an O-ring 12 attached to the outer peripheral surface thereof. is doing.

  A pressure plate 7 disposed on the bottom surface side of the circular recess 6 of the front body 4 includes a disc portion 7a constituting the other side wall of the pump chamber 11 and a cylinder formed on the axial core portion of the disc portion 7a. The disc portion 7a is fitted to the inner peripheral surface of the circular recess 6 of the front body 4. An O-ring 13 is mounted on the outer periphery of the disc portion 7a to prevent pressure oil from leaking through the gap between the disc portion 7a and the front body 4. The pressure plate 7 is disposed on the bottom surface side of the circular recess 6 of the front body 4, an adapter ring 9 is fitted on the outer periphery of the pressure plate 7, and the cam ring 8 and the rotor 3 are fitted inside the adapter ring 9. Is housed.

  The cam ring 8 is used to increase or decrease the pump capacity of the variable displacement pump 1, and the adapter ring 9 uses the seal pin 14 provided on the lower side of FIG. 9 is swingably supported. The cam ring 8 is urged to the left in FIG. The urging means 15 includes a plug 16 screwed to the front body 4 and a compression coil spring 17 elastically mounted between the plug 16 and the cam ring 8. The compression coil spring 17 is inserted through a through hole 9 a formed in the adapter ring 9 and is in contact with the cam ring 8.

  The cam ring 8 includes a first fluid pressure chamber 21 formed in one of the swing directions (left side in FIG. 9) and a second fluid pressure chamber 22 formed in the other swing direction, which will be described later. By selectively supplying pressure oil from the valve 23, it is reciprocally swung. The first fluid pressure chamber 21 and the second fluid pressure chamber 22 are defined by the seal pin 14 and a seal member 24 mounted in an axially symmetric position with respect to the seal pin 14 of the cam ring 8, and the seal pin 14 and The seal member 24 maintains liquid tightness between the fluid pressure chambers 21 and 22.

  The rotor 3 disposed inside the cam ring 8 is connected to a drive shaft 25 to which power is transmitted from an engine (not shown). The rotor 3 is held on the outer peripheral side of the rotor 3 so as to be able to protrude and retract on the inner peripheral cam surface of the cam ring 8. A large number of vanes 27 in sliding contact are provided. A drive shaft 25 that rotates the rotor 3 is rotatably supported in the pump body 2 via bearings 28, 29, and 30. The rotor 3 rotated by the drive shaft 25 rotates in the counterclockwise direction of FIG. 9 (see the arrow in the figure).

  As shown in FIG. 10, the variable displacement pump 1 is configured such that hydraulic oil is pumped from a suction pipe 31 and a suction passage 31 a fixed to the rear body 5 through a suction port 32 formed in the convex portion 5 a of the rear body 5. It is designed to be sucked into the chamber 11. The hydraulic oil sucked into the pump chamber 11 passes through the discharge port 33 formed in the disk portion 7 a of the pressure plate 7 and is discharged into the discharge pressure chamber 34 formed in the bottom portion of the front body 4. . As shown in FIG. 9, the discharge amount of the variable displacement pump 1 becomes maximum when the cam ring 8 swings to the left side of the figure, and decreases when the cam ring 8 swings to the right side of the figure. It is supposed to be.

  The discharge pressure chamber 34 is annularly formed between the outer peripheral side of the cylindrical portion 7 b of the pressure plate 7 and the bottom surface of the circular recess 6 of the front body 4. A discharge passage 35 is connected to the upper portion of the discharge pressure chamber 34 in FIG. 10, and the pressure oil discharged from the pump chamber 11 to the discharge pressure chamber 34 is fed from the discharge passage 35 to the power steering device PS. The As shown in FIG. 10, the discharge passage 35 has a portion 35a extending from the discharge pressure chamber 34 radially outward of the rotor 3, and a lateral portion 35b extending in a direction orthogonal to the radial portion 35a. An oil supply pipe (not shown) for supplying pressure oil to the power steering device PS is connected to the end of the lateral portion 35b. Further, a metering orifice 36 (see FIG. 11) is provided in the lateral portion 35b of the discharge passage 35.

  The control valve 23 has a configuration in which a spool 38 is slidably fitted in a valve hole 37 formed in the front body 4. The spool 38 divides the inside of the valve hole 37 into first to fourth oil chambers 41 to 44, and is moved to the left in FIGS. 11 and 12 by a compression coil spring 45 disposed in the fourth oil chamber 44. It is energized. The first oil chamber 41 is always connected to the upstream side of the metering orifice 36 provided in the lateral portion 35 b of the discharge passage 35 via a communication passage 46. The second oil chamber 42 is connected to the suction port 32 of the rear body 5 through communication passages 47 and 48 (see FIG. 10).

  As shown in FIG. 11, the third oil chamber 43 is located upstream of the metering orifice 36 by the communication passage 50 in a state where the spool 38 is pressed by the compression coil spring 45 and is in contact with the stopper 49. Connected to the side. The fourth oil chamber 44 is connected to the downstream side of the metering orifice 36 by a communication passage 51. The fourth oil chamber 44 is connected to the second oil chamber 42 via a relief valve 52 provided in the spool 38 as shown in FIG.

  As shown in FIG. 9, the valve hole 37 of the control valve 23 is connected to the first fluid pressure chamber 21 by the first connection passage 53, and the second fluid is connected by the second connection passage 54. Connected to the pressure chamber 22. The opening positions of the connection passages 53 and 54 on the valve hole 37 side are such that the first connection passage 53 is in the second oil chamber when the spool 38 is in contact with the stopper 49 as shown in FIG. 42, the second connecting passage 54 is connected to the third oil chamber 43, and, as shown in FIG. 12, in the state where the spool 38 has moved to the right side of the figure, The connection passage 53 is connected to the first oil chamber 41, and the second connection passage 54 is connected to the second oil chamber 42.

  In the conventional variable displacement pump 1 having the above-described configuration, when the engine speed is in a low rotation range including idling rotation (range A to B in FIG. 13), the upstream side and the downstream side of the metering orifice 36 11 is small, the spool 38 of the control valve 23 is pressed against the stopper 49 by the elastic force of the compression coil spring 45, as shown in FIG.

  In this state, the pressure of the suction port 32 from the second oil chamber 42 of the control valve 23 acts on the first fluid pressure chamber 21, and the discharge pressure from the third oil chamber 43 acts on the second fluid pressure chamber 22. (Pressure on the upstream side of the metering orifice 36) acts. As a result, the cam ring 8 is held at the position shown in FIG. 9, and the pump capacity of the pump chamber 11 formed between the rotor 3 and the cam ring 8 is maximized, so that the discharge amount is maximized.

  As the engine speed increases and the pressure oil flow rate through the discharge passage 35 increases, the pressure difference between the upstream side and downstream side of the metering orifice 36 increases. As the pressure on the upstream side of the metering orifice 36 increases, the pressure in the first oil chamber 41 of the control valve 23 increases, and the spool 38 resists the elastic force of the compression coil spring 45 as shown in FIG. And move right. As a result, the discharge pressure from the first oil chamber 41 acts on the first fluid pressure chamber 21, and the pressure of the suction port 32 from the second oil chamber 42 acts on the second fluid pressure chamber 22. . For this reason, the cam ring 8 swings to the right in FIG. 9 against the elastic force of the compression coil spring 17 of the biasing means 15, the capacity of the pump chamber 11 is reduced, and the discharge amount becomes constant. When the cam ring 8 swings to the right end in FIG. 9 during high speed operation (point C in FIG. 13), the minimum discharge amount is constant.

  The conventional variable displacement pump 1 according to the above configuration has a problem that the amount of energy loss increases in an operation state with a large discharge amount, and it is clear that the cause of this problem is leakage of pressure oil. became. That is, at the time of low rotation (range A to B in FIG. 13), the pressure upstream of the metering orifice 36 is introduced into the second fluid pressure chamber 22 as described above. The high-pressure oil supplied to the fluid pressure chamber 22 flows into the first connection passage 53 through a minute annular gap outside the adapter ring 9, and from here, the lowest pressure in the control valve 23. This is caused by leakage into the second oil chamber 42. Since the pressure oil discharged from the variable displacement pump 1 is reduced by this amount of leakage, to compensate for this, the engine speed must be increased to increase the discharge amount, as described above. The amount of energy loss increases.

  The annular minute gap where pressure oil leaks is formed between the first gap formed between the adapter ring 9 and the front body 4 and the rear body 5 and the pressure plate 7 to seal the pump chamber 11. A second gap formed along the mounted O-rings 12 and 13 is considered.

  The first gap is considered to be formed by the deformation of the adapter ring 9 and the front body 4 due to the pressure oil acting on the outer peripheral surface of the adapter ring 9. Pressure oil in the second fluid pressure chamber 22 leaks into the gap from a through hole 9 a for the biasing means 15 of the adapter ring 9 and a gap formed between the rear body 5 and the pressure plate 7. In order to prevent the pressure oil from leaking through the first gap, the structure in which the adapter ring 9 is stopped and the cam ring is directly attached to the front body 4 may be employed. However, in order to adopt this structure, the front body 4 must be divided and formed with a high accuracy equivalent to that of the adapter ring 9, so that the cost is remarkably increased.

  On the other hand, in the second gap, the O-rings 12 and 13 attached to the rear body 5 and the pressure plate 7 are pressed and compressed by the hydraulic pressure of the second fluid pressure chamber 22, and the O-ring accommodating portions 12a and 13a (FIG. 10). It is thought that it is formed by the expansion of the vacant space in (see). In order to prevent the pressure oil from leaking through the second gap, the front body 4, the rear body 5, the pressure plate 7, etc. are arranged so that the pressure oil does not act on the O-ring housing portions 12 a, 13 a. Since the fitting portion has to be formed so that the gap is as narrow as possible, the cost increases as described above.

  Further, the conventional variable displacement pump 1 has a problem that the discharge pressure always acts on the second fluid pressure chamber 22 at the time of low rotation, so that the pump body 2 has to be formed firmly and becomes large. .

  Accordingly, the inventor of the present invention invented a variable displacement pump that efficiently discharges pressure oil while preventing the pressure oil from leaking inside the pump while reducing costs, and has already filed an application (Patent Document 2). reference).

  In the invention according to the application, a cam ring is swingably supported inside an adapter ring, and a first fluid pressure chamber is formed on one side of the swing direction of the cam ring, and a second fluid pressure chamber is formed on the other side. And an urging means for urging the cam ring in the direction in which the volume of the pump chamber is maximized, and the upstream side of the metering orifice provided in the middle of the discharge passage in the first and second fluid pressure chambers. In a variable displacement pump operated by a differential pressure with the downstream side and connected with a control valve for controlling the hydraulic pressure in the fluid pressure chambers on both sides of the cam ring, the control valve has a difference between the upstream side and the downstream side of the metering orifice. When the pressure is low, a closing portion for closing the port connected to the second fluid pressure chamber is provided.

In the variable displacement pump according to the application, since the pressure oil does not flow into the second fluid pressure chamber at the time of low rotation, the pressure oil leaks through the gap inside the pump through the second fluid pressure chamber. In addition, since the discharge pressure does not always act on the second fluid pressure chamber, there is an excellent effect that the pump body is not enlarged to increase the strength. it can.
Japanese Patent Laid-Open No. 6-200883 (page 4-7, FIG. 1) Japanese Patent Application No. 2000-216446 (page 5-8, FIG. 2)

  The present invention is obtained by further improving the variable displacement pump according to Patent Document 2, and is formed in the pump body or in the adapter ring without impairing the return performance to the side where the volume of the pump chamber increases. By eliminating the need for a passage hole connecting the control valve and the second fluid pressure chamber, the number of processing steps can be reduced, and further, no high pressure is instantaneously applied to the second fluid pressure chamber, An object of the present invention is to provide a variable displacement pump capable of increasing the pressure of the pump without increasing the size of the pump body. Moreover, when the pump discharge pressure becomes high, the variable displacement type can reduce internal leakage by reducing the side clearance by pressing one plate against the other plate and reducing the pump efficiency. The object is to provide a pump.

  A variable displacement pump according to a first aspect of the present invention is a cam ring that is swingably supported between plates on both sides, a first fluid pressure chamber provided in one of the swing directions of the cam ring, A second fluid pressure chamber provided on the other side of the swinging direction; an urging means provided on the second fluid pressure chamber side for urging the cam ring toward the first fluid pressure chamber side; A rotor having a plurality of vanes disposed on the outer peripheral side, a metering orifice provided in the middle of a discharge passage of the pressure fluid discharged from the pump, and a pressure difference between the upstream side and the downstream side of the metering orifice A control valve operated by the control valve, and the cam ring is swung by controlling the fluid pressure of at least one of the fluid pressure chambers by the operation of the control valve. A discharge port for the pressure fluid discharged from the pump chamber is provided in one of the ports, and a seal ring surrounding the periphery of the drive shaft that drives the roller is provided behind the other plate, and the first seal ring A second seal ring surrounding a region wider than the region where the discharge port is provided is provided on the outer peripheral side, and an introduction passage for introducing discharge pressure is formed in a region between the two seal rings. It is.

  According to a second aspect of the present invention, both the seal rings are made of resin, communicated with the seal grooves into which the seal rings are fitted, and a recess deeper than the seal grooves is formed. The discharge pressure is introduced into the inside.

  In the variable displacement pump according to the first aspect of the present invention, the discharge pressure is introduced between the inner and outer seal rings provided on one plate, and the other of the plate, the cam ring, the rotor, and the adapter ring on which the discharge port is formed. Therefore, as the pump discharge pressure becomes higher, the side clearance becomes smaller and it is possible to prevent the pump efficiency from being lowered due to internal leakage.

  In the variable displacement pump according to the second aspect of the present invention, the resin seal ring is supported from behind by the high-pressure oil introduced into the recess, so that the blow-by phenomenon can be prevented.

  A cam ring is supported between the plates on both sides so as to be swingable. A first fluid pressure chamber is provided on one side of the swing direction of the cam ring, a second fluid pressure chamber is provided on the other side, and the cam ring is provided on the second fluid pressure chamber side. The cam ring is biased toward the first fluid pressure chamber by the biasing means. A rotor arranged eccentrically in the cam ring and provided with a plurality of vanes in a rotor rotated by a drive shaft, in the middle of a discharge passage for pressure fluid discharged from a pump chamber formed between two adjacent vanes A metering orifice is provided, and the control valve is operated by a pressure difference between the upstream side and the downstream side. By operating this control valve, the pressure in the fluid pressure chamber is controlled to swing the cam ring. A pressure fluid projecting port is provided on one of the two plates, and on the back side of the other plate, the first seal ring surrounding the periphery of the drive shaft, and wider than the region where the discharge port is provided. A second seal ring surrounding the range is provided, and an introduction passage for introducing discharge pressure is formed in a region between the two seal rings. When the pump is operated, one of the two plates sandwiching the cam ring and the rotor, etc. To the other plate side to reduce the side clearance and reduce the internal leakage.

  Hereinafter, the present invention will be described with reference to embodiments shown in the drawings. FIG. 1 is a sectional view perpendicular to the axis of a drive shaft of a variable displacement pump according to an embodiment of the present invention. FIG. 2 is a sectional view taken along the axis of the drive shaft of the variable displacement pump. The same or corresponding parts as those of the conventional configuration described with reference to FIGS.

  This variable displacement pump (generally indicated by reference numeral 101) is used as a hydraulic pressure supply source of a power steering device of an automobile, and the power of an engine (not shown) is transmitted to the drive shaft 25 so that the rotor 3 rotates. It has become. In this embodiment, as indicated by an arrow R in FIG. 1, the drive shaft 25 and the rotor 3 rotate in the counterclockwise direction.

  The variable displacement pump 101 includes a side plate 7, an adapter ring 9, an inner cam ring 8, a rotor 3, and a pressure in a pump body 2 formed by abutting the front body 4 and the rear body 5 from the bottom side of the front body 4. The plate 160 is inserted in order, and the circular protrusion 5 a of the rear body 5 is inserted into the opening of the front body 4 and fixed by the bolt 10.

  As described above, the rotor 3 is connected to the drive shaft 25 and is rotated by transmission of engine power. Further, the cam ring 8 is supported on the outer peripheral side of the rotor 3 in the adapter ring 9 so as to be eccentric with respect to the rotation center Or of the rotor 3 (axial center of the drive shaft 25) and swingable. A support plate 162 having a rolling support surface 162a perpendicular to the vertical line M passing through the rotation center Or of the rotor 3 is disposed on the inner surface of the adapter ring 9, and the cam ring 8 is supported by the support plate 162. 1 can swing between the side plate 7 and the pressure plate 160 in the left-right direction in FIG. Further, by inserting this support plate 162, the cam ring 8 is slightly shifted upward in FIG. 2 (to the suction port 32 side described later). In this embodiment, a vane is used as the support plate 162 that supports the swinging of the cam ring 8 to ensure the strength of the support surface 162a of the cam ring 8, and between the two fluid pressure chambers 21 and 22 described later. The seal is done.

  A first fluid pressure chamber 21 (left side in FIG. 1) and a second fluid pressure chamber 22 (right side in FIG. 1) are formed on both sides of the cam ring 8 in the swing direction. A seal member 24 is attached to the adapter ring 9 at an axially symmetric position with respect to the support plate 162. The fluid pressure chambers 21 and 22 are partitioned by the support plate 162 and the seal member 24, and liquid tightness is maintained. ing. When the cam ring 8 swings in the left direction in FIG. 1, the volume of the pump chamber 11 formed by the two adjacent vanes 27 and 27 between the plates 7 and 160 becomes maximum, and the right direction When swung, the volume of the pump chamber 11 is reduced. A spring (biasing means) 17 is disposed on the second fluid pressure chamber 22 side, and constantly biases the cam ring 8 in a direction in which the volume of the pump chamber 11 is maximized. The pin 164 provided near the support plate 162 is a detent pin that positions the side plate 7, adapter ring 9, and pressure plate 160.

  An arc-shaped suction port 32 is formed in a region of the side plate 7 where the volume of the pump chamber 11 gradually expands as the rotor 3 rotates (the suction region in the upper part of FIG. 1). The working fluid sucked from the tank through the passage 31 is supplied to the pump chamber 11. Further, a discharge port 33 is opened in a region of the side plate 7 where the volume of the pump chamber 11 is gradually reduced with the rotation of the rotor 3 (discharge region in the lower part of FIG. 1). The pressure fluid discharged from the pump chamber 11 through the outlet 33 is introduced into the discharge side pressure chamber 34 formed at the bottom of the pump body 2. The discharge side pressure chamber 34 is connected to the discharge port 166 via a discharge passage 135 formed in the pump body 2, and the pressure fluid introduced into the discharge side pressure chamber 34 is supplied from the discharge port 166 to the power steering device. It is sent to the PS power cylinder.

  A control valve 123 is provided in the pump body 2 in a direction orthogonal to the drive shaft 25. The control valve 123 has a spool 138 slidably fitted in a valve hole 137 formed in the pump body 2. The spool 138 is constantly illustrated by a compression coil spring 145 disposed in a chamber 144 (hereinafter referred to as a spring chamber) on one end (the second fluid pressure chamber 22 side end on the right side in FIG. 1) side. 1 is biased toward the left (in the direction of the first fluid pressure chamber 21), and when not in operation, is screwed into the opening of the valve hole 137 to hit the front surface of the plug 168 that closes the valve hole 137. It has stopped.

  A metering orifice 136 is provided in the middle of the discharge passage 135 from the pump chamber 11 to the power steering device PS, and the fluid pressure upstream of the metering orifice 136 passes through a pilot pressure passage (not shown). 1 is introduced into the left chamber 141 (hereinafter referred to as a high pressure chamber), while the fluid pressure downstream of the metering orifice 135 is introduced into the spring chamber 144 via the pilot pressure passage 151. When the pressure difference between the two chambers 141 and 144 exceeds a predetermined value, the spool 138 moves to the right in FIG. 1 against the compression coil spring 145. In this embodiment, the metering orifice 136 is a fixed orifice. However, the variable orifice disclosed in Japanese Patent Application No. 2000-216446 or Japanese Patent Application No. 2000-368119 may be used. good.

  The first fluid pressure chamber 21 formed on the left side of the cam ring 8 communicates with the valve hole 137 on the high pressure chamber 141 side via connection passages 2 a and 9 a formed in the pump body 2 and the adapter ring 9. On the other hand, the second fluid pressure chamber 22 formed on the right side of the cam ring 8 has no connection passage provided in the conventional variable displacement pump and is not directly connected to the control valve 123. The second fluid pressure chamber 22 is communicated with the suction passage 31 through the introduction hole 170 formed in the side plate 7 so that the pressure on the suction side is constantly introduced.

  A first land portion 138a that partitions the high pressure chamber 141 and a second land portion 138b that partitions the spring chamber 144 are formed on the outer peripheral surface of the spool 138, and an annular groove portion 138c is formed between these land portions 138a and 138b. Is provided. The intermediate annular groove 138c is connected to the tank via a pump suction side passage 148 (see FIG. 2), and the space between the annular groove 138c and the inner peripheral surface of the valve hole 137 is the pump suction side chamber 142. Is configured.

  The first fluid pressure chamber 21 provided on the left side of the cam ring 8 is connected to the pump suction side chamber 142 via the connection passages 2a and 9a when the spool 138 is in the inoperative position shown in FIG. When the spool 138 is actuated by the differential pressure before and after 136, the pump suction side chamber 142 is gradually cut off and communicated with the high pressure chamber 141. Accordingly, the pressure on the pump suction side and the pressure on the upstream side of the metering orifice 136 provided in the pump discharge passage 135 are selectively supplied to the first fluid pressure chamber 21.

  A relief valve 152 is provided inside the spool 138, and the pressure in the spring chamber 144 (pressure on the downstream side of the metering orifice 136, in other words, operating pressure of the power steering device PS) exceeds a predetermined level. It opens when it rises, and this fluid pressure is released to the tank side.

  Furthermore, in the variable displacement pump 101 according to this embodiment, the positions of the suction port 32 and the discharge port 33 formed in the side plate 7 are provided at positions shifted in the rotational direction as compared with the conventional configuration. ing.

  As shown in FIG. 3, the basic structure of the variable displacement pump is that the center Or of the rotor 3 (the axis of the drive shaft 25) and the center Oc of the cam ring 8 are located on the same horizontal line N. The pump chamber 11 has the maximum volume when the two vanes 27 and 27 provided in the rotor 3 are in a vertically symmetrical position of the horizontal line N. The pump chamber 11 is switched from the suction port 32 to the discharge port 33 when the pump chamber 11 reaches the maximum volume.

  On the other hand, in the configuration of this embodiment, as shown in FIG. 4, the side plate 7 in which the discharge port 33 and the suction port 32 are formed is rotated about 2.5 ° in the clockwise direction in FIG. The center Oc of the cam ring 8 is shifted slightly above the horizontal line N through which the center Or of the rotor 3 passes. Therefore, the pump chamber 11 formed by the two adjacent vanes 27 and 27 reaches a maximum volume before reaching the symmetrical position across the horizontal line N. In addition, when the volume of the pump chamber 11 reaches the maximum, the pump chamber 11 is connected to the end portion 32 a side of the suction port 32 so that it does not reach the start end portion 33 a of the discharge port 33. Therefore, when the preceding vane 27 (the vane indicated by reference numeral 27a in FIG. 4) of the two vanes 27 forming the pump chamber 11 reaches the start end portion 33a of the discharge port 33, the pump chamber 11 is already Compression has started. That is, pre-compression is performed.

  As described above, the suction port 32 and the discharge port 33 are shifted in the rotation direction, and the cam ring 8 is slightly lifted toward the suction port 32. Therefore, when the pump is operated, High pressure acts over a range. Therefore, an internal pressure is applied to the cam ring 8 so as to always return toward the position where the volume of the pump chamber 11 is maximized (the first fluid pressure chamber 21 side).

  Furthermore, in the variable displacement pump 101 of this embodiment, as shown in FIG. 5, two seal rings 172 and 174 are fitted on the surface of the pressure plate 160 on the rear body 5 side. As these seal rings 172, 174, resin rings are used in this embodiment. An inner peripheral seal ring (first seal ring) 172 is disposed around a hole 160a through which the drive shaft 25 passes. Further, the outer peripheral seal ring (second seal ring) 174 surrounds the outside of the discharge port 33 formed in the side plate 7 in the discharge side region (lower region in FIG. 5), and In the region, the first seal ring 172 is disposed at a position close to the first seal ring 172.

  As shown in FIGS. 6 and 7, the pressure plate 160 has a first annular groove (seal groove) 160b into which a first seal ring 172 and a second seal ring 174 are fitted, respectively, as shown in FIGS. A second annular groove 160c is formed. Furthermore, in the first annular groove 160b in which the first seal ring 172 is fitted, circular concave portions 160d having a diameter substantially equal to the width of the groove 160b are arranged at equal intervals in the circumferential direction and substantially the diameter thereof. Four positions are formed at positions shifted to the outside of the groove 160b by half. In addition, in the second annular groove 160c to which the second seal ring 174 is fitted, circular recesses 160e having a diameter substantially equal to the width of the groove 160c are arranged at equal intervals in the circumferential direction and substantially the diameter thereof. Four places are formed at positions shifted to the inside of the groove 160c by one-half. These circular recesses 160d and 160e are deeper than the seal grooves 160b and 160c. By introducing high-pressure oil into these circular recesses 160d and 160e, the seal rings 172 and 174 are supported from behind, The blow-by, that is, the pressure oil passing over the seal rings 172 and 174 is prevented from failing to perform the sealing function.

  The pressure plate 160 is formed with an arc-shaped groove 160f and a through hole 160g at a position corresponding to the discharge port 33 formed in the side plate 7, so that the pump discharge pressure is on the rear body 5 side of the pressure plate 160. A surface is introduced between the seal rings 172 and 174.

  A pump discharge pressure acts on the surface of the side plate 7 on the front body 4 side over the portion where the discharge port 33 is formed and its peripheral portion, and the discharge pressure is applied to the side plate 7. The area of the pressure plate 160 surrounded by the seal rings 172 and 174 is larger than the area of the pressure plate 160. Therefore, when the pump is operated, the pressure plate 160 presses the rotor 3, the cam ring 8 and the adapter ring 9 toward the side plate 7, and the rotor 3, the cam ring 8 and the adapter ring 9, and the side plate 7 and the pressure plate 160 on both sides thereof. The side clearance between is made small. In particular, the higher the pump discharge pressure, the stronger the pressure against the side plate 7 side, the smaller the side clearance, and the loss due to internal leakage can be prevented.

  The operation of the variable displacement pump 101 having the above configuration will be described. Since the hydraulic pressure does not act on the control valve 123 when the pump is stopped, the spool 138 of the control valve 123 abuts against the plug 168 as a stopper by the elastic force of the compression coil spring 145 and stops. When the engine is started in this state, the rotational speed of the variable displacement pump 101 increases as the engine speed increases.

  Since the pressure difference between the upstream side and the downstream side of the metering orifice 136 is small while the engine speed is low, the spool 138 of the control valve 123 is stopped at the position shown in FIG. 2 by the compression coil spring 145. Yes. When the control valve 123 is not in operation, the pressure on the pump suction side is introduced into the first fluid pressure chamber 21 on the left side of the cam ring 8 from the pump suction side chamber 142 of the control valve 123 via the connection passages 2a and 9a. The pressure on the pump suction side is constantly introduced into the second fluid pressure chamber 22 on the right side of the cam ring 8 through the introduction hole 170. Therefore, the cam ring 8 is held by the spring 17 at a position where the volume of the pump chamber 11 shown in FIG. 2 is maximized, and the variable displacement pump 101 increases the discharge amount in proportion to the increase in the rotational speed. (Refer the range of AB of FIG. 13).

  As the engine speed increases, the discharge flow rate from the pump chamber 11 gradually increases, and the pressure difference between the upstream side and the downstream side of the metering orifice 136 increases. The spool 138 moves in the direction in which the compression coil spring 145 is bent (in the direction of the spring chamber 144), and connects the high pressure chamber 141 to the first fluid pressure chamber 21. The spool 138 is balanced at a predetermined position. That is, the spool 138 can connect the high pressure chamber 141 to the first fluid pressure chamber 21 formed on one side (left side in FIG. 2) of the cam ring 8 and connect or connect the pump suction side. Almost stable in condition.

In such an equilibrium state of the spool 138 of the control valve 123, the cam ring 8 swings to the right in FIG. 2 due to the differential pressure between the fluid pressure chambers 21 and 22 on both sides and the biasing force of the compression coil spring 17. Thus, the pump chamber 11 is balanced at a position where the pump discharge flow rate becomes the minimum. In this state, for example, when the pump discharge pressure is 150 kg / cm ² , the hydraulic pressure in the first fluid pressure chamber 21 is balanced at about 2 kg / cm ² , so that internal leakage can be achieved without processing the seal 24 and the like with high precision. There is little possibility to cause.

  Further, when the steering operation is performed in the equilibrium state as described above, the operating pressure of the power steering device PS rises, and this pressure enters the spring chamber 44 of the control valve 123 via the passage 151, and the spool 138 It acts on the end surface on the spring chamber 144 side. When the spool 138 is pushed back to the left in FIG. 1 by the operating pressure of the power steering device PS, the first fluid pressure chamber 21 on the left side of the cam ring 8 is replaced with the high pressure chamber 141 into which the upstream pressure of the metering orifice 136 is introduced. And is connected to the pump suction side chamber 142. The fluid pressure chambers 21 and 22 on both sides of the cam ring 8 are at the pressure on the pump suction side, and the cam ring 8 is pumped by the spring 17 on the second fluid pressure chamber 22 side and the pressure acting on the inner peripheral side thereof. Oscillates in a direction in which the volume of the lens increases.

  That is, in the variable displacement pump 101 according to this embodiment, the positions of the suction port 32 that supplies hydraulic oil to the pump chamber 11 and the discharge port 33 that discharges hydraulic oil from the pump chamber 11 are the positions of the conventional variable displacement pump 1. 2 is shifted in the rotational direction (clockwise direction in FIG. 2), and the pressure acting on the inner surface of the cam ring 8 (the range of D to E in FIG. 4 becomes high pressure) It acts in the direction to return to the indicated position. Therefore, even if the second fluid pressure chamber 22 is always at the pressure on the pump suction side, the cam ring 8 can quickly return to the direction in which the volume of the pump chamber 11 increases, and the discharge amount can be increased.

  In the configuration of the conventional variable displacement pump (Japanese Patent Laid-Open No. 6-200883), the pump discharge pressure (pressure upstream of the metering orifice 136) is supplied to the second fluid pressure chamber 22 in the region from A to B in FIG. Since there is a possibility that internal leakage may occur due to the direct action, the processing accuracy of the seal portion such as the inner diameter of the pump body 2 and the outer diameter of the adapter ring 9 is required to suppress the internal leakage. However, in the configuration of this embodiment, high processing accuracy of the seal portion is unnecessary, and internal leakage can be improved. Moreover, vibration sound due to pulsation can also be improved. Furthermore, the pump body 2 can be increased in pressure without increasing the size of the pump body 2 and increasing the strength.

  In addition, the variable displacement pump disclosed in Japanese Patent Application No. 2000-216446 (Patent Document 2) invented and filed by the inventor of the present invention can solve the problems of the conventional variable displacement pump. However, since a high pressure is instantaneously applied to the second fluid pressure chamber when the spool of the control valve is operated, there is a concern of internal leakage at that moment. On the other hand, in the configuration of the embodiment of the present invention, since the pressure on the pump suction side is always introduced into the second fluid pressure chamber 22, it is further advantageous to cope with the high pressure of the pump. In addition, in the invention according to the application, a connection passage that connects the control valve and the second fluid pressure chamber is provided. In this embodiment, the connection between the control valve 123 and the second fluid pressure chamber 22 is used. Since passages (oil passage holes formed in the pump body 2 and the adapter ring 9) are unnecessary, the number of processing steps can be reduced and the cost can be reduced.

  Next, a second embodiment will be described with reference to FIG. In this figure, the alternate long and short dash line indicates the rotor 3, the solid line indicates the position of the cam ring 8A when the pump discharge capacity is maximum, and the broken line indicates the position of the cam ring 8B when the pump discharge capacity is minimum. In the first embodiment, in order to apply the internal pressure of the cam ring 8 in the direction in which the cam ring 8 swings toward the first fluid pressure chamber 21, the discharge port 33 formed in the side plate 7 and While the suction port 32 is shifted in the rotation direction, the cam ring 8 is slightly biased toward the suction port 32 (upward in FIGS. 2 and 4). In this embodiment, the positions of the discharge port 33 and the suction port 32 are as follows. The position may be symmetrical in the vertical direction as in the conventional configuration. In this embodiment, parts not shown will be described with the same reference numerals as those in the first embodiment.

  In this embodiment, the support plate 162 disposed on the inner surface of the adapter ring 9 and supporting the cam ring 8 is disposed on the second fluid pressure chamber 22 side (in FIG. 8) with respect to the vertical line M passing through the center Or of the rotor 3. The rolling support surface 162a is inclined toward the first fluid pressure chamber 21 direction (left direction in FIG. 8). Further, the center Oc of the cam ring 8 (the center of the cam ring 8 when the pump discharge capacity is maximum is indicated by OcA, and the center of the cam ring 8 when the pump discharge capacity is minimum is indicated by OcB) is a horizontal line passing through the center Or of the rotor 3. It is positioned slightly above N.

  The configuration of the other parts is the same as that of the first embodiment. When the cam ring 8 is swung in the direction in which the pump discharge capacity decreases (right direction in FIG. 1), the pump discharge pressure is controlled. This is done by introducing it into the first fluid pressure chamber 21. On the contrary, when the cam ring 8 is returned in the direction in which the pump discharge capacity is increased (the left direction in FIG. 1), the swing fulcrum 12 of the cam ring 8 is in the second fluid pressure chamber rather than the shaft core Or of the rotor 3. Since the cam ring internal pressure due to the pump discharge pressure acts at a right angle on the rolling support surface 162a, the component force is the first because it is arranged on the side 22 and is inclined toward the first fluid pressure chamber 21. The cam ring 8 quickly returns due to the internal pressure of the cam ring 8 in addition to the force of the spring 17 acting in the direction of the fluid pressure chamber 21. Also in this embodiment, the internal leakage can be improved by always connecting the second fluid pressure chamber to the pump suction side, and the position of the swing support surface of the cam ring is set to the second fluid pressure chamber side. Therefore, when the pump discharge flow rate needs to be increased, the cam ring can be quickly returned.

  As described above, the variable displacement pump according to the present invention is provided with the discharge port 33 for the pressure fluid discharged from the pump chamber 11 on one of the two plates (side plate 7) sandwiching the cam ring 8. The first seal ring 172 that surrounds the periphery of the drive shaft 25 that drives the rotor 3 is formed on the back surface of the other plate (pressure plate 160), and the discharge port 33 on the outer peripheral side of the first seal ring 172. Since the second seal ring 174 surrounding the wider area than the area where the seal ring is provided is provided, and the introduction passage 160g for introducing the discharge pressure is formed in the area between the seal rings 172 and 174, the cam ring is operated during the pump operation. 8 and one side 160 of the two plates 7 and 160 sandwiching the rotor 3 etc. are pressed against the other plate 7 side to clear the side. By reducing the Nsu, you are possible to reduce internal leakage.

  In addition, this invention is not limited to the structure demonstrated in the said Example, It cannot be overemphasized that the shape of each part, a structure, etc. can be deform | transformed and changed suitably. For example, the angle for rotating the discharge port and the suction port of the first embodiment, the position for shifting the rolling support surface of the cam ring of the second embodiment, etc. are not limited to the configuration of the above embodiment, It is possible to select appropriately.

Next, inventions other than the invention described in the above claims that can be grasped from the contents of the above-described embodiments will be described.
1. A cam ring supported so as to be swingable between the plates on both sides, a first fluid pressure chamber provided in one of the swing directions of the cam ring, and a second fluid pressure chamber provided in the other of the swing directions of the cam ring; A biasing means that is provided on the second fluid pressure chamber side and biases the cam ring toward the first fluid pressure chamber; a rotor that is eccentrically arranged in the cam ring and has a plurality of vanes on the outer peripheral side; A metering orifice provided in the middle of the discharge passage of the pressure fluid discharged from the pump, and a control valve that operates according to a pressure difference between the upstream side and the downstream side of the metering orifice. In the variable displacement pump that swings the cam ring by controlling the fluid pressure of at least one of the fluid pressure chambers,
The control valve and the first fluid pressure chamber are connected to control the fluid pressure in the first fluid pressure chamber, and the second fluid pressure chamber is disconnected from the control valve and always connected to the pump suction side, A variable displacement pump characterized in that the internal pressure of the cam ring acts in a direction in which the cam ring swings toward the first fluid pressure chamber.

  In the variable displacement pump according to the present invention, the oil passage from the control valve to the second fluid pressure chamber is eliminated, and the pressure on the pump suction side is always introduced into the second fluid pressure chamber. It does not act, vibration noise due to internal leakage or pulsation is improved, and there is no need to enlarge the pump body for strength. Moreover, in order to return the cam ring to the direction in which the pump volume is maximized, the internal pressure of the cam ring is set in the return direction in addition to the spring force, so that the cam ring can be returned in a stable and quick operation.

2. A cam ring supported so as to be swingable between the plates on both sides, a first fluid pressure chamber provided in one of the swing directions of the cam ring, and a second fluid pressure chamber provided in the other of the swing directions of the cam ring; A biasing means that is provided on the second fluid pressure chamber side and biases the cam ring toward the first fluid pressure chamber; a rotor that is eccentrically arranged in the cam ring and has a plurality of vanes on the outer peripheral side; A metering orifice provided in the middle of the discharge passage of the pressure fluid discharged from the pump, and a control valve that operates according to a pressure difference between the upstream side and the downstream side of the metering orifice. In the variable displacement pump that swings the cam ring by controlling the fluid pressure of at least one of the fluid pressure chambers,
The control valve and the first fluid pressure chamber are connected to control the fluid pressure in the first fluid pressure chamber, and the second fluid pressure chamber is disconnected from the control valve and always connected to the pump suction side, Furthermore, the rolling support surface that supports the cam ring so as to be able to roll is disposed on the second fluid pressure chamber side with respect to the axis of the rotor, and is inclined toward the first fluid pressure chamber side. Variable displacement pump.

3. The variable displacement pump according to claim 1, wherein
The position of the end of the suction port and the start of the discharge port formed on the plates arranged on both sides of the cam ring are shifted toward the suction port side in the circumferential direction, and the cam ring is biased toward the suction port side. Thus, the variable displacement pump is characterized in that the internal pressure of the cam ring acts toward the first fluid pressure chamber side.

It is sectional drawing orthogonal to the axis line of the drive shaft of a variable displacement pump. Example 1 It is sectional drawing along the axis line of the drive shaft of the said variable displacement pump. It is a figure explaining the positional relationship of the rotor and cam ring of a conventional variable displacement pump, a discharge port, and a suction port. It is a figure explaining the positional relationship of the rotor and cam ring, discharge port, and suction port of the variable displacement pump which concerns on the said Example. It is a front view which shows the structure of the seal | sticker part provided in the side surface of the pressure plate of the said variable displacement pump. It is a front view of the pressure plate. It is a longitudinal cross-sectional view of the pressure plate. It is a figure explaining the positional relationship of the cam ring of a variable displacement pump of another structure, a rotor, and the rolling fulcrum of a cam ring. (Example 2) It is sectional drawing orthogonal to the axis line of the drive shaft of the conventional variable displacement pump. It is sectional drawing along the axis line of the drive shaft of the conventional variable displacement pump. It is sectional drawing which shows the structure of the control valve and discharge passage of the conventional variable displacement pump. It is sectional drawing which shows the structure of the control valve and discharge passage of the conventional variable displacement pump, and shows the operation state different from FIG. It is a graph which shows the relationship between pump discharge amount and rotation speed.

Explanation of symbols

3 rotor 7 plate (side plate)
8 Cam ring 17 Biasing means (spring)
21 First fluid pressure chamber 22 Second fluid pressure chamber 27 Vane 33 Discharge port 123 Control valve 135 Discharge passage 136 Metering orifice 160 Plate (pressure plate)
160g introduction passage) (through hole)
172 First seal ring 174 Second seal ring

Claims (2)

A cam ring supported so as to be swingable between the plates on both sides, a first fluid pressure chamber provided in one of the swing directions of the cam ring, and a second fluid pressure chamber provided in the other of the swing directions of the cam ring; A biasing means that is provided on the second fluid pressure chamber side and biases the cam ring toward the first fluid pressure chamber; a rotor that is eccentrically arranged in the cam ring and has a plurality of vanes on the outer peripheral side; A metering orifice provided in the middle of the discharge passage of the pressure fluid discharged from the pump, and a control valve that operates according to a pressure difference between the upstream side and the downstream side of the metering orifice. In the variable displacement pump that swings the cam ring by controlling the fluid pressure of at least one of the fluid pressure chambers,
A discharge port for the pressure fluid discharged from the pump chamber is provided in one of the two plates that sandwich the cam ring, and a back surface of the other plate surrounds the periphery of the drive shaft that drives the rotor. One seal ring and a second seal ring that surrounds the area wider than the area where the discharge port is provided are provided on the outer peripheral side of the first seal ring, and discharge pressure is introduced into the area between the two seal rings. A variable displacement pump characterized in that an introduction passage is formed. The variable displacement pump according to claim 1, wherein
Both the seal rings are resin rings, communicated with a seal groove into which the seal ring is fitted, and a recess deeper than the seal groove is formed, and discharge pressure is introduced into the recess. Variable displacement pump.

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