JP3598831B2 - Flow control device for working fluid for power steering - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a motive power for controlling a flow rate of a working fluid to be sent to a power steering device by driving a flow rate adjusting spool valve in accordance with a differential pressure before and after passing through a throttle passage to adjust an opening degree of a bypass passage. The present invention relates to a flow control device for a steering working fluid. More specifically, the present invention relates to a flow control device configured to return an excess flow of a working fluid supplied from a pump or the like to a bypass passage.
[0002]
[Prior art]
When the vehicle is running at high speed, it is desirable to increase the steering reaction force perceived by the driver, and to reduce the control flow rate to the power steering device in accordance with the increase in the pump speed, a so-called speed-responsive type. Has been developed.
[0003]
As a flow control device having such a function, a pressure difference is generated before and after a fixed throttle based on an increase in a discharge flow rate due to an increase in a pump rotation speed, and the control spool forms a throttle passage by the pressure difference and a control spool. The opening area of the throttle passage is variably controlled by overcoming the spring interposed and displaced toward the throttle member, and when the pump rotation speed reaches a constant rotation speed, the control flow rate Q is lowered as shown in FIG. There is something like that. FIG. 13 shows a required flow rate characteristic of the control flow rate Q with respect to the pump rotation speed N.
[0004]
FIG. 11 shows a flow control device corresponding to the required flow characteristics.
In this flow control device, a discharge oil (hydraulic oil) is supplied from a pressure chamber of an existing vane pump via a supply path 41, and a flow control valve 40 having a bypass recirculation mechanism for recirculating excess hydraulic oil to a bypass passage 42. Is a basic configuration. In addition to these, the supply path 41 connected to the pressure chamber is provided toward the oil introduction chamber 43 in the flow control valve 40. The flow control valve 40 is provided with a sub-spool 44 as a control spool. A fixed throttle 45 and an oil introduction passage 46 are provided between the sub-spool 44 and the oil introduction chamber 43. I have.
[0005]
The fixed throttle 45 is provided in a direction in which the spool 47 is operated, whereas the oil introduction passage 46 is provided toward a shoulder 48 of the sub-spool 44. A throttle member 39 is provided downstream of the sub-spool 44, and a throttle passage 49 is provided in the throttle member 39. As shown in FIG. 12, a pair of the throttle passages 49 are formed apart from each other in the radial direction about the center axis O of the fluid passage 51 of the sub spool 44.
[0006]
Downstream of the throttle passage 49, a delivery port 50 for delivering hydraulic oil to the power assist unit C of the power steering device is provided. The pressure generated before and after the throttle passage 49 acts before and after the spool 47, respectively.
[0007]
With such a configuration, when the pump starts operating, the discharge oil (operating oil) guided from the supply path 41 to the oil introduction chamber 43 via the pressure chamber is discharged from the fixed throttle 45 to the flow control valve 40. Then, the air is sent from the outlet 50 to the power assist unit C via the fluid passage 51 and the throttle passage 49 in the sub-spool 44. Here, when the pump discharge amount increases, the spool 47 slides due to the pressure difference generated before and after the throttle passage 49, and the opening area with the bypass passage 42 is controlled. , A constant discharge flow rate (see constant flow rate control in FIG. 13).
[0008]
When the pump rotation speed further increases, the hydraulic pressure in the oil introduction chamber 43 increases by the fixed throttle 45 according to the pump rotation speed. As a result, the force applied to the shoulder 48 of the sub-spool 44 from the oil introduction path 46 also increases, and as a result, the sub-spool 44 moves rightward against the spring force of the spring 52. As a result, the cylindrical distal end 53 of the sub-spool 44 comes into contact with the surface of the throttle passage 49 and closes a part of the opening of the throttle passage 49 (see FIG. 12). In FIG. 12, a hatched area is an opening of a portion narrowed by the distal end portion 53 in the throttle passage 49. As a result, the flow rate of the discharge oil sent from the outlet 50 to the power assist unit C through the throttle passage 49 is reduced and limited to a constant value, so that the so-called drooping control function is exhibited. (See drooping control in FIG. 13).
[0009]
In FIGS. 11 and 12, reference numeral 54 denotes a cutout groove provided on the sub-spool-side end surface of the throttle member 39. The notch groove 54 is for preventing the pressure of the working oil acting on the cylindrical tip of the sub spool 44 from changing when the sub spool 44 approaches the throttle member 39.
[0010]
[Problems to be solved by the invention]
In the case of the throttle member 39, for example, when the control flow rate Q during the constant flow rate control is a predetermined value A and the control flow rate B during the drooping control is a large difference (flow rate difference) between the predetermined values A and B, As shown in FIG. 14, the actual flow rate characteristics substantially match the required flow rate characteristics.
[0011]
Therefore, in the case of the required flow rate characteristic in which the difference (flow rate difference) between the control flow rate A during the constant flow rate control and the control flow rate B during the drooping control is small, that is, the control flow rate during the constant flow rate control is the same, When it is desired to increase the flow rate at the time of control, it is conceivable that the opening area (full opening area) of each of the throttle passages 49 is the same and the pitch between the throttle passages 49 provided in the throttle member 39 is narrowed. FIG. 15 shows a case where the pitch of the throttle passage 49 is narrower than that of FIG. As shown in the figure, the hatched area of the portion not covered by the tip 53 of the sub-spool 44 is wider than in FIG.
[0012]
As a result, the flow rate characteristic of FIG. 15 is the same as that of FIG. 12 at the time of the constant flow rate control in which the sub-spool 44 does not move. It will be a larger flow rate than the one.
[0013]
However, when the flow rate characteristic is actually measured using the throttle member 39 of FIG. 15, as shown in FIG. 16, the pump rotation speed range in which the constant flow rate control is to be performed, and the difference between the constant flow rate control and the drooping control are shown. It has been found that the flow rate increases in the range of the pump rotational speed at which the transition is to be performed. That is, there is a problem that a linear flow characteristic cannot be obtained.
[0014]
In FIG. 16, the control flow rate C is the control flow rate flowing during the drooping control, and is larger than the control flow rate B in FIG. Also, in FIG. 16, the dotted line indicates the required flow rate characteristic during the constant flow rate control.
[0015]
As a result of examining this phenomenon, the throttle passage 49 is located closer to the center axis O of the fluid passage 51 having a good flow efficiency, so that the sub-spool 44 does not restrict the throttle passage 49. It is presumed that the flow becomes easier and the flow rate increases.
[0016]
This is because when hydraulic oil is passed through the throttle passage, if the total opening area of the throttle passage is the same, one large throttle passage is provided on the center axis O side of the fluid passage 51 in consideration of the flow efficiency. For the same reason that it gets better.
[0017]
If the above constant flow control and the middle control flow swell as shown in FIG. 16 and a linear flow characteristic cannot be obtained, particularly at the time of transition between the constant flow control and the drooping control, a sense of discomfort is large. There is a problem.
[0018]
An object of the present invention is to provide a power source capable of obtaining a linear flow characteristic even in a range of a pump speed where a control flow rate changes when a flow rate difference between a control flow rate during a constant flow rate control and a control flow rate during a drooping control is small. An object of the present invention is to provide a flow control device for steering working fluid.
[0019]
[Means for Solving the Problems]
According to the first aspect of the present invention, a throttle member is provided in a fluid passage leading to a power steering device from a pump, and the throttle member is formed on a circumference radially separated from a center of the fluid passage in the throttle member. A fixed throttle is provided upstream of the throttle passage, and a flow adjusting spool for adjusting an opening degree of a bypass passage that slides by a differential pressure of the working fluid before and after the throttle passage to return an excess flow to the inflow side of the pump is provided. A control spool that slides by a differential pressure of the working fluid before and after the passage of the fixed throttle, and a tubular portion that throttles in a form that closes a part of the throttle passage on the throttle passage side of the control spool; A notch is formed at a position not corresponding to the throttle passage on the end surface of the throttle member, or at a position corresponding to the cylindrical portion excluding the throttle passage on the control spool side end surface of the throttle member, and the throttle is formed corresponding to the notch. The members include The cylindrical part of Inside diameter At a position radially away from Correspondingly An essential feature of the present invention is a power control device for power steering working fluid, wherein an auxiliary throttle passage whose opening area does not vary depending on the cylindrical portion is provided.
[0020]
According to a second aspect of the present invention, in the first aspect, when the control spool does not block a part of the throttle passage, the auxiliary throttle passage is actuated by a flow restricting means for reducing the amount of working fluid flowing through the throttle passage. A gist of the present invention is a flow control device of a working fluid for power steering in which a fluid passage amount is suppressed.
[0021]
According to a third aspect of the present invention, in the second aspect, the flow rate suppressing means is configured by making an opening area of the auxiliary throttle passage smaller than an opening area of the throttle passage.
[0022]
According to a fourth aspect of the present invention, in the second or third aspect, the flow rate suppressing means moves the installation position of the auxiliary throttle passage from a center of the fluid passage. Than the throttle passage The gist of the invention is that it is configured to be set at a position spaced apart in the radial direction.
[0023]
According to a fifth aspect of the present invention, in any one of the first to fourth aspects, a plurality of the auxiliary throttle passages are provided.
(Action)
According to the first aspect of the present invention, when the pump starts operating, the working fluid is sent from the fixed throttle to the power steering device via the throttle passage.
[0024]
When the pump rotation speed increases and the discharge flow rate from the pump increases, the flow rate adjusting spool valve is operated by the action of the pressure difference generated before and after the throttle passage, and the opening area with the bypass passage is adjusted. As a result, the surplus hydraulic oil is bypass-recirculated to the bypass passage, and constant flow control is performed.
[0025]
Furthermore, when the pump rotation speed increases, the working fluid pressure before passing through the fixed throttle increases according to the rotation speed by the fixed throttle. As a result, the cylindrical portion of the control spool operates to reduce the opening area of the throttle passage.
[0026]
Further, in the auxiliary throttle passage provided corresponding to the notch, the working fluid flows through the notch when the cylindrical portion moves to the throttle passage side to reduce the opening area of the throttle passage or after the throttle is completed. .
[0027]
For this reason, the delivery flow rate of the working fluid delivered to the power steering device via the throttle passage decreases, and drooping control is performed. Also, when the cylindrical portion moves to reduce the opening area of the throttle passage, the working fluid flows through the notch and the auxiliary throttle passage, so that even when shifting from the constant flow control to the drooping control, it is linear. A good flow characteristic can be obtained.
[0028]
According to the second aspect of the present invention, in addition to the operation of the first aspect, the working fluid flowing through the throttle passage by the flow rate suppression means when the control spool does not block a part of the throttle passage. It is made smaller than the passing amount, and the working fluid passing amount is suppressed. According to the third aspect of the present invention, in addition to the operation of the first or second aspect, the control spool is provided with the flow control means that the opening area of the auxiliary throttle passage is smaller than the opening area of the throttle passage. Is not closed, the flow rate of the working fluid flowing through the throttle passage is reduced, and the flow rate of the working fluid is suppressed.
[0029]
According to the fourth aspect of the invention, in addition to the function of any one of the first to third aspects, the installation position of the auxiliary throttle passage is set from the center of the fluid passage. Than the throttle passage When the control spool does not block a part of the throttle passage, the throttle passage closer to the center of the fluid passage is easier to pass when the control spool does not block a part of the throttle passage. The fluid flows into the throttle passage, and the flow rate of the working fluid passing through the auxiliary throttle passage is suppressed.
[0030]
According to the fifth aspect of the present invention, by providing a plurality of auxiliary throttle passages, when the cylindrical portion moves to the throttle passage side to reduce the opening area of the throttle passage, or when the throttle is completed, the notch is cut out. , The flow rate of the working fluid flowing can be increased.
[0031]
BEST MODE FOR CARRYING OUT THE INVENTION
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the present invention is embodied in a flow control device used in a power steering device of an automobile will be described with reference to the drawings.
[0032]
FIG. 1 shows a cross section of the flow control device 1. The flow control device 1 is slid by the differential pressure across the throttle passage 16 and adjusts the degree of opening to the bypass passage 5 to control the flow to a constant flow (constant flow control), a spool valve 9, a spring 13, and the like. And a drooping mechanism including a fixed throttle 10, a sub-spool valve 15, a spring 19, and the like.
[0033]
The flow control device 1 is provided in a pump housing 2 of a hydraulic pump driven by an engine. The pump housing 2 is formed with a valve housing hole 3 whose one end is closed. An oil introduction chamber 3a is formed inside the valve housing hole 3, and a supply passage 4 communicating with the discharge port of the hydraulic pump is opened to the oil introduction chamber 3a. A bypass passage 5 communicating with a suction port of the hydraulic pump is opened inside the valve housing hole 3 separated from the supply passage 4.
[0034]
A union 6 is screwed into the opening end of the valve housing hole 3. The union 6 is formed with a through hole 7 penetrating in the axial direction. In the through hole 7, the inner end is a small diameter portion 7a as a union pressure chamber, and the outer end side is a large diameter portion 7b. An outlet member 8 is fitted on the large-diameter portion 7b side of the through hole 7. The delivery port member 8 is formed in a cylindrical shape, and sends out a working oil as a working fluid from the delivery port member 8 to a power steering device (not shown). At the inner end of the union 6, a communication passage 7c is formed in the radial direction, and the small diameter portion 7a communicates with a first valve chamber 11 described later.
[0035]
A spool valve 9 for adjusting the flow rate (hereinafter referred to as a spool valve) 9 is slidably fitted in the valve housing hole 3. The spool valve 9 closes a communication passage between the supply passage 4 and the bypass passage 5 and adjusts an opening degree of the communication passage. The spool valve 9 forms a first valve chamber 11 between the spool valve 9 and the union 6.
[0036]
A second valve chamber 12 is formed between the spool valve 9 and the closed portion of the valve housing hole 3. A spring 13 for pressing the spool valve 9 toward the first valve chamber 11 is provided in the second valve chamber 12. The elastic force of the spring 13 always acts so as to hold the spool valve 9 at a position where it contacts the one end of the union 6. As a result, communication between the supply passage 4 opening to the first valve chamber 11 and the bypass passage 5 is interrupted in a normal state.
[0037]
An orifice forming member 14 as a throttle member is fitted into the through hole 7 of the union 6. The orifice forming member 14 is formed in a cylindrical shape with a bottom, and is engaged with the inner end of the sending / outlet member 8 to be integrally connected.
[0038]
In the through hole 7 of the union 6, a sub-spool valve 15 is slidably disposed along the axial direction of the union 6. As shown in FIG. 1, the sub-spool valve 15 has a small-diameter cylindrical portion 15a that slides on the small-diameter portion 7a of the through hole 7 and a large-diameter bulging portion that slides on the large-diameter portion 7b of the through hole 7. 15b, and a small-diameter cylindrical portion 15c protruding from the bulging portion 15b toward the orifice forming member 14. The cylindrical portion 15c has a predetermined thickness in the radial direction. In each part of the sub-spool valve 15, a flow hole 15d is formed along the center axis O. The flow holes 15d constitute a fluid passage of the present invention.
[0039]
A spring 19 is arranged between the bulging portion 15b of the sub-spool valve 15 and the orifice forming member 14, and regulates the movement of the sub-spool valve 15. Normally, the spring 19 presses the sub-spool valve 15 leftward in FIG. 1 (the direction opposite to the direction in which the hydraulic oil flows), and the shoulder 15e of the bulging portion 15b is pressed against the large-diameter portion 7b. It is configured to abut and lock on the locking step. The end face of the cylindrical portion 15c of the sub-spool valve 15 can be brought into contact with and locked to the end face of the orifice forming member 14.
[0040]
A fluid chamber 21 is formed between the sub spool valve 15 and the orifice forming member 14.
A throttle passage 16 is formed on the inner bottom surface of the orifice forming member 14. Two throttle passages 16 are provided at positions corresponding to the cylindrical portion 15c on a circumference centered on the central axis O of the sub spool valve 15. That is, as shown in FIG. 3B, the respective throttle passages 16 are arranged so as to be located at positions opposite to each other by 180 degrees with respect to the central axis O. When the cylindrical portion 15c of the sub-spool valve 15 contacts the end face of the orifice forming member 14, a part of the throttle passage 16 is closed by the cylindrical portion 15c, so that the throttle passage 16 is narrowed. That is, the opening area of the throttle passage 16 is reduced by the cylindrical portion 15c. The opening area after the squeezing is determined by the radial thickness of the cylindrical portion 15c.
[0041]
A pair of grooves 17 is formed in the end face of the orifice forming member 14 on the side of the sub spool valve 15. Both grooves 17 are arranged so as to correspond to the cylindrical portion 15c except for the vicinity of the throttle passage 16 as shown in FIG. When the cylindrical portion 15c of the sub-spool valve 15 contacts the end face of the orifice forming member 14, the groove surrounded by the groove 17 and the flow hole 15d of the cylindrical portion 15c communicate with each other. A relationship between the width of 17 (width in the left-right direction in FIG. 3B) and the thickness of the cylindrical portion 15c is set. The groove 17 corresponds to the notch of the present invention.
[0042]
There is no change in the pressure of the hydraulic oil due to the approach of the sub-spool valve 15 to the orifice forming member 14 in the cylindrical portion 15 c corresponding to the groove 17, and the moving speed of the sub-spool valve 15 increases as it approaches the orifice forming member 14. Is never faster. Further, in a state where the sub-spool valve 15 is in contact with the orifice forming member 14, the pressure of the working oil after the fixed throttle 10 can also act on the cylindrical portion 15c corresponding to the groove 17, so that after the fixed throttle 10 Due to the pressure increase, a large force acts to move the sub-spool valve 15 to the spool valve 9 side.
[0043]
One auxiliary throttle passage 18 is formed in one groove 17, and the auxiliary throttle passage 18 communicates the groove 17 with the outlet of the outlet member 8. The auxiliary throttle passage 18 has an opening area smaller than the opening area of the throttle passage 16 when it is not throttled by the cylindrical portion 15c. As shown in FIG. 3B, the auxiliary throttle passage 18 is arranged at a position radially away from the center axis O of the sub spool valve 15 (that is, the center of the flow hole 15c). The opening area of the auxiliary throttle passage 18 is made smaller than the opening area of the throttle passage 16, and the auxiliary throttle passage 18 is disposed at a position radially away from the central axis O of the sub-spool valve 15 (that is, the center of the flow hole 15 c). Each configuration constitutes the flow rate suppressing means of the present invention.
[0044]
Therefore, the first valve chamber 11 and the outlet of the outlet member 8 are communicated with each other through the flow hole 15d, the throttle passage 16 and the auxiliary throttle passage 18.
In the orifice forming member 14, a communication hole 14 a is formed in a region between the throttle passage 16 and the outlet member 8, and communicates with a peripheral groove 14 b provided on the outer periphery of the orifice forming member 14.
[0045]
In the union 6, a communication path 20 is formed in a region corresponding to the peripheral groove 14a. The communication passage 20 communicates with the second valve chamber 12 via a communication passage 21 formed in the pump housing 2.
[0046]
Therefore, most of the part of the working oil as the working fluid passes through the throttle passage 16, and the remaining part passes through the auxiliary throttle passage 18 and is then introduced into the second valve chamber 12. Therefore, the pressure of the hydraulic oil before passing through the throttle passage 16 and the pressure of the hydraulic oil after passing through the throttle passage 16 mainly act on both sides of the spool valve 9. As a result, the spool valve 9 moves in the axial direction in response to the pressure drop in the throttle passage 16 to keep the pressure drop in the throttle passage 16 constant, that is, to make the differential pressure across the throttle passage 16 constant. The opening degree of the bypass passage 5 is adjusted.
[0047]
In the first valve chamber 11, a fixed throttle 10 is formed on the outer periphery of the union 6 so as to be located between the oil introduction chamber 3a and the bypass passage 5. The fixed throttle 10 is provided in a direction in which the spool valve 9 is operated. Further, a through passage 6 a communicating with the oil introduction chamber 3 a is formed on the outer periphery of the union 6. The through passage 6a is opened at the locking step of the large diameter portion 7b.
[0048]
When the pump rotation speed is low, the sub-spool valve 15 is urged by the spring 19, the shoulder of the bulging portion 15b abuts and locks on the locking step of the large diameter portion 7b, and the cylindrical portion 15c is locked. The throttle passage 16 is separated from the throttle passage 16 in the axial direction. At this time, the cross-sectional area of the flow path of the throttle passage 16 (that is, the opening area of the throttle passage 16) becomes large.
[0049]
When the pump rotation speed increases, the sub-spool valve 15 moves rightward from the state of FIG. 1 against the spring 19 and forms an orifice so that the cylindrical portion 15 c closes a part of the throttle passage 16. It contacts the member 14. Therefore, the opening area of the throttle passage 16 is reduced by the cylindrical portion 15c.
[0050]
The spool valve 9 is provided with a pressure relief valve 24, and when the pressure in the second valve chamber 12 becomes equal to or higher than a preset pressure, the relief valve 24 spools the pressure in the second valve chamber 12 The gas is released to the bypass passage 5 through the relief passage 25 formed in the valve 9.
[0051]
Next, the operation of the flow control device 1 configured as described above will be described.
When the pump starts operating by the vehicle engine and discharge oil (working oil) as a working fluid is introduced from the supply passage 4 into the oil introduction chamber 3a, the working oil is discharged from the fixed throttle 10 to the flow control valve 1. , Through the small-diameter portion 7a of the through hole 7, the flow passage 15d in the sub-spool valve 15, the throttle passage 16, and the auxiliary throttle passage 18, from the outlet member 8 to the power steering device (not shown).
[0052]
By the way, when the pump rotational speed is low, the discharge flow rate of the hydraulic oil is small, so that the spool valve 9 closes the bypass passage 5 as shown in FIG. It is sent to the power steering device via the auxiliary throttle passage 18.
[0053]
At this time, although the cylindrical portion 15c and the orifice forming member 14 are separated from each other, the auxiliary throttle passage 18 is located at a position separated from the center axis O of the flow passage 15d as shown in FIG. Since the opening area of the auxiliary throttle passage 18 is smaller than the opening area of the throttle passage 16 and the passage resistance is larger than that of the throttle passage 16, the operation is not performed. Most of the oil passes through the throttle passage 16 located on the extension of the flow hole 15d, and the amount of the working fluid passing through the auxiliary throttle passage 18 is limited and suppressed.
[0054]
Next, when the pump rotation speed increases and the discharge flow rate increases, the spool valve 9 moves leftward against the spring 13 mainly due to the action of the differential pressure across the throttle passage 16 (FIG. 4). At this time, since the bypass passage 5 is not opened, the discharge flow rate increases from the point O to the point A in FIG. When the spool valve 9 moves leftward from the state shown in FIG. 1 against the spring 13 and opens the bypass passage 5 (see FIG. 5), the excess hydraulic oil flows from the first valve chamber 11 to the bypass passage 5. The constant flow rate control is performed while maintaining the flow rate Q1 shown in FIG. The point B in FIG. 8 is the state in FIG.
[0055]
Thereafter, when the pump rotation speed further increases and the flow rate of the working oil supplied to the oil introduction chamber 3a increases, the sub-spool valve 15 expands from the through passage 6a which is the pressure on the front side (upstream side) of the fixed throttle 10. The pressure introduced into the shoulder 15f of the outlet 15b increases. Therefore, the sub-spool valve 15 moves rightward against the elastic force of the spring 19. At this time, the opening area of the throttle passage 16 is reduced and reduced by the cylindrical portion 15c of the sub-spool valve 15 (see FIGS. 2, 3B, and 6). As a result, a drooping effect is exhibited, and the drooping control is performed while maintaining the flow rate Q2 shown in FIG. FIG. 6 shows a state at point C in FIG.
[0056]
At this time, there is no change in the pressure of the hydraulic oil due to the approach of the sub-spool valve 15 to the orifice forming member 14 in the cylindrical portion 15c corresponding to the groove 17, and as the sub-spool valve 15 approaches the orifice forming member 14, The speed of movement does not increase.
[0057]
After the cylindrical portion 15c abuts on the orifice forming member 14, a part of the hydraulic oil (that is, the non-recirculated hydraulic oil) is supplied to the outlet member 8 through the throttle passage 16 having a reduced opening area. After flowing through the auxiliary throttle passage 18 via the groove 17, the remainder flows toward the outlet member 8 side.
[0058]
Therefore, the pressure of the hydraulic oil before passing through the throttle passage 16 and the pressure of the hydraulic oil after passing through the throttle passage 16 mainly act on both sides of the spool valve 9. As a result, the spool valve 9 moves in the axial direction in response to the pressure drop in the throttle passage 16 to keep the pressure drop in the throttle passage 16 constant, that is, to make the differential pressure across the throttle passage 16 constant. The opening degree of the bypass passage 5 is adjusted.
[0059]
In the state where the drooping control is being performed, when the pump rotation speed further increases, the spool valve 9 moves in the axial direction in accordance with the pressure drop in the throttle passage 16 due to the above. In order to keep the pressure drop constant, the opening degree of the bypass passage 5 is further adjusted to increase the reflux flow rate (see FIG. 7). The state in FIG. 7 shows the state at point D in FIG.
[0060]
Next, features of the flow control device 1 configured as described above will be described below.
(1) In the present embodiment, the sub-spool valve 15 is provided with the cylindrical portion 15c, the orifice forming member 14 is provided with the auxiliary throttle passage 18 in the groove 17, and the cylindrical portion 15c reduces the opening area of the throttle passage 16. After closing and reducing the size, a part of the hydraulic oil is sent out through the auxiliary throttle passage 18.
[0061]
Therefore, even when the cylindrical portion 15c moves to reduce the opening area of the throttle passage 16, the hydraulic oil flows through the groove 17 and the auxiliary throttle passage 18, so that the control shifts from the constant flow control to the drooping control. In this case, a linear flow characteristic can be obtained.
[0062]
Further, since the hydraulic oil can be delivered from the auxiliary throttle passage 18, the flow rate Q1 during the constant flow rate control is made the same, and the flow rate Q2 during the drooping control is increased. By making the auxiliary throttle passage 18 carry all or a part of the desired flow rate, it is not necessary to narrow the pitch between the pair of throttle passages 16.
[0063]
Conventionally, in order to obtain the flow rate Q2 at the time of the drooping control, it was necessary to narrow the pitch of the two throttle passages 16. In this case, as shown by the line α in FIG. The flow increases when transitioning between drooping controls. With this α-ray characteristic, the flow rate sharply decreases and the process shifts to drooping control.
[0064]
However, in this embodiment, the flow rate becomes like β-ray, and a more linear flow rate characteristic can be obtained as compared with the related art. In FIG. 8, the γ line is a required flow characteristic line, and the δ line is a flow characteristic line when the flow rate during drooping control is set small without providing an auxiliary throttle passage.
[0065]
Instead of the auxiliary throttle passage, a passage may be provided between the two throttle passages 16 so as to include, for example, the central axis O. In this case, at the time of the constant flow rate control, the hydraulic oil flows through the throttle passage and the passage. However, the passage including the central axis O is a central region where the hydraulic oil flows, and the flow passage resistance is smaller than that of the throttle passage. Since the flow rate is small, that is, the efficiency is high, there is a problem that the flow rate expands at the time of constant flow rate control, and the same effect as in the present embodiment cannot be obtained.
[0066]
(2) In the present embodiment, the opening area of the auxiliary throttle passage 18 is smaller than the opening area of the throttle passage 16. As a result, when the cylindrical portion 15c of the sub-spool valve 15 does not block a part of the throttle passage 16, the flow rate of the hydraulic oil flowing through the throttle passage 16 is reduced, and the flow rate of the hydraulic oil can be suppressed. Therefore, at the time of the constant flow control, the flow can be sent at a constant flow without expanding the flow.
[0067]
(3) In the present embodiment, the installation position of the auxiliary throttle passage 18 is set at a position radially separated from the central axis O of the flow hole 15d. As a result, when the cylindrical portion 15c of the sub-spool valve 15 does not block a part of the throttle passage 16, the flow rate of the hydraulic oil flowing through the throttle passage 16 is reduced, and the flow rate of the hydraulic oil can be suppressed. Therefore, at the time of the constant flow control, the flow can be sent at a constant flow without expanding the flow.
[0068]
Note that the present invention is not limited to only the above-described embodiment, and may be implemented as follows.
(1) In the above embodiment, one auxiliary throttle passage 18 is provided, but one auxiliary throttle passage 18 may be provided in each groove 17 as shown in FIG. By doing so, the flow of the hydraulic oil becomes uniform in the vertical direction and the horizontal direction in the figure, and the hydraulic pressure is balanced, so that the operation of the sub-spool valve 15 becomes smoother.
[0069]
(2) The number 18 of the auxiliary throttle passages 18 may be three or more. However, the opening area is smaller than the opening area of the throttle passage 16.
(3) In each of the above embodiments, the relationship between the throttle passage 16 and the auxiliary throttle passage 18 has been described in terms of the size of the opening area. However, the size of the opening area is one parameter that determines the flow resistance of the hydraulic oil. Not just. As another factor that determines the flow path resistance, for example, there is a path length, and the flow path resistance varies depending on the path length. Therefore, in the present invention, the relationship between the throttle passage and the auxiliary throttle passage is preferably such that the auxiliary throttle passage is smaller than the throttle passage in the passage resistance. May be set.
[0070]
(4) In the above embodiment, the groove 17 is provided in the orifice forming member 14. Instead of omitting the groove 17, a notch groove 15g as a notch is formed in the end face of the cylindrical portion 15c as shown in FIG. Accordingly, an auxiliary throttle passage 18 may be formed in the orifice forming member 14 corresponding to the notch groove 15g. In this case, the notch groove 15g communicates with the flow hole 15d and has a width that does not block the opening of the non-throttle member 18.
[0071]
Also, like the groove 17, the notched groove 15g has no change in the hydraulic oil pressure in the cylindrical portion 15c due to the approach of the sub-spool valve 15 to the orifice forming member 14, and the sub-spool valve 15 has the orifice forming. This achieves an operation in which the moving speed does not increase as approaching the member 14.
[0072]
Further, when the sub-spool valve 15 is in contact with the orifice forming member 14, the pressure of the working oil after the fixed throttle 10 can also act on the cylindrical portion 15c via the notch groove 15f. An effect is exerted in which a force for moving the sub-spool valve 15 toward the spool valve 9 due to a subsequent pressure rise acts greatly.
[0073]
(5) In the above embodiment, the opening area of the auxiliary throttle passage 18 is smaller than the opening area of the throttle passage 16, and the installation position of the auxiliary throttle passage 18 is radially separated from the central axis O of the flow hole 15 d. Although the position is set, only one of them may be realized.
[0074]
Here, in addition to the technical ideas described in the claims, the technical ideas grasped by the above-described embodiments are listed below together with their effects.
(1) The flow control device for a power steering working fluid according to claim 1, wherein the notch is a notch groove provided in the control spool. With this configuration, in the notched groove, the pressure of the hydraulic oil does not change in the cylindrical portion due to the approach of the control spool to the throttle member, and the moving speed of the control spool does not increase as the control spool approaches the throttle member. effective.
[0075]
Further, in a state where the control spool is in contact with the throttle member, the pressure of the hydraulic oil after the fixed throttle can be applied to the cylindrical portion via the notch groove. The force for moving the spool toward the flow rate adjusting spool can be exerted greatly.
[0076]
【The invention's effect】
As described in detail above, according to the first to fifth aspects of the present invention, the pump in which the control flow rate changes when the flow rate difference between the control flow rate during the constant flow rate control and the control flow rate during the drooping control is small. A linear flow characteristic can be obtained even in the rotation speed range. Further, since the auxiliary throttle passage is provided, it is not necessary to increase the opening area of the throttle passage even when the working fluid passage amount is increased during the drooping control.
[0077]
According to the invention described in claims 2 to 4, when the control spool does not block a part of the throttle passage, the auxiliary throttle passage is larger than the working fluid passage amount flowing through the throttle passage by the flow rate suppressing means. The flow rate of the working fluid can be reduced, and the predetermined flow rate can be maintained during the constant flow rate control.
[0078]
According to the invention of claim 5, by providing a plurality of auxiliary throttle passages, when the cylindrical portion moves to the throttle passage side to reduce the opening area of the throttle passage, or after the completion of the throttle, through the notch, The flow rate of the flowing working fluid can be increased.
[Brief description of the drawings]
FIG. 1 is a sectional view of a power steering working fluid flow control device according to an embodiment of the present invention.
FIG. 2 is a sectional view of a main part of the power steering working fluid flow control device.
3A is a cross-sectional view of a main part taken along line aa of FIG. 3B, FIG. 3B is a front view of an orifice forming member, and FIG. 3C is a cross-sectional view of main part taken along line cc of FIG. FIG.
FIG. 4 is a sectional view showing the operation of the flow control device of the embodiment.
FIG. 5 is a sectional view showing the operation of the flow control device of the embodiment.
FIG. 6 is a sectional view showing the operation of the flow control device according to the embodiment;
FIG. 7 is an exemplary sectional view showing the operation of the flow control device according to the embodiment;
FIG. 8 is a flow characteristic diagram of the flow control device of the embodiment.
FIG. 9 is a front view of an orifice forming member according to another embodiment.
FIG. 10 is a sectional view of a main part of a flow control device according to another embodiment.
FIG. 11 is a sectional view showing the operation of a conventional flow control device.
FIG. 12 is a front view of a conventional orifice forming member.
FIG. 13 is a required flow characteristic diagram of the flow control device.
FIG. 14 is an actual flow characteristic diagram of the flow control device.
FIG. 15 is a front view of a conventional orifice forming member.
FIG. 16 is an actual flow characteristic diagram of the flow control device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Flow control device, 2 ... Pump housing, 3 ... Valve storage hole,
4: supply passage, 5: bypass passage, 6: union, 6a: through passage,
9: Flow adjustment spool valve (constituting a flow adjustment spool)
10: fixed throttle, 11: first valve chamber, 12: second valve chamber, 13: spring,
14 orifice forming member (constituting a throttle member);
15 ... Sub-spool valve (constituting control spool)
15c: cylindrical portion, 15d: flow hole (constituting a fluid passage),
15g: Notch groove (constituting notch), 16: throttle passage,
17: groove (constituting notch) 18: auxiliary throttle passage, 19: spring.

Claims (5)

A throttle member is provided in a fluid passage from the pump to the power steering device,
A throttle passage is formed in the throttle member on a circumference radially separated from the center of the fluid passage,
A fixed throttle is provided upstream of the throttle passage, and a flow adjusting spool for adjusting an opening degree of a bypass passage that slides by a differential pressure of the working fluid before and after the throttle passage to return an excess flow to the inflow side of the pump is provided.
A control spool that slides by a differential pressure of the working fluid before and after passing the fixed throttle is provided,
A cylindrical portion is formed on the throttle passage side of the control spool so as to block a part of the throttle passage,
A notch is formed at a position not corresponding to the throttle passage on the throttle member side end surface of the cylindrical portion, or at a position corresponding to the cylindrical portion excluding the throttle passage at the control spool side end surface of the throttle member,
Wherein the diaphragm member in response to cut-out and characterized in that in response to a position spaced radially from the inner diameter of the tubular portion, by the tubular portion is provided with an auxiliary throttle passage opening area is not variable Power steering working fluid flow control device. The auxiliary throttle passage is characterized in that, when the control spool does not block a part of the throttle passage, the flow rate of the working fluid is suppressed by a flow rate suppression unit that is smaller than the flow amount of the working fluid flowing through the throttle passage. The flow control device for a working fluid for power steering according to claim 1. The flow rate control device for a power steering working fluid according to claim 2, wherein the flow rate suppression means is configured by making an opening area of the auxiliary throttle passage smaller than an opening area of the throttle passage. 4. The flow control device according to claim 2, wherein the flow restricting unit is configured by setting an installation position of the auxiliary throttle passage at a position radially away from the center of the fluid passage than the throttle passage. 5. Control device for power steering working fluid. The flow control device for a power steering working fluid according to any one of claims 1 to 4, wherein a plurality of the auxiliary throttle passages are provided.

Images