The disclosure of Japanese Patent Application No. 2011-183147 filed on Aug. 24, 2011 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
The present invention relates to an electromagnetic pump device in which a strainer is attached to a suction port.
Hitherto, there has been proposed an electromagnetic pump device of this type, including an electromagnetic portion, a movable iron core capable of moving back and forth in the axial direction inside a pump chamber by turning on and off the electromagnetic portion, an inlet check valve mechanism that is built in the pump chamber and that allows working oil to flow in one direction from a suction port into the pump chamber, and an outlet check valve mechanism that is built in the pump chamber and that allows working oil to flow in one direction from the pump chamber to a discharge port (see Japanese Patent Application Publication No. 2006-291914 (JP 2006-291914 A), for example). In the electromagnetic pump device, the suction port extends in the axial direction from the inlet check valve mechanism, and opens in a direction orthogonal to the axial direction to be connected to an oil passage. A strainer is attached at the connection portion to remove foreign matter such as dust. In order to reduce the resistance against flow of the working oil through the strainer, a stepped portion is formed such that the portion of connection with the oil passage is slightly larger in diameter than the suction port.
In some of the thus configured electromagnetic pump devices, the inlet check valve mechanism is formed with a suction port that opens in the axial direction, and the strainer is disposed immediately before the inlet check valve mechanism. Also in such devices, it is conceivable to provide the stepped portion discussed above at the suction port in the inlet check valve mechanism. In order to provide the stepped portion, however, it is necessary to make the suction port of the inlet check valve mechanism slightly larger in inside diameter and then expand the inlet check valve mechanism in the axial direction, which may make the inlet check valve mechanism larger to lead to an increase in size of the electromagnetic pump device.
It is a main object of the electromagnetic pump device according to the present invention to smoothly suck a working fluid and have a compact configuration.
In order to achieve the foregoing main object, the electromagnetic pump device according to the present invention adopts the following means.
According to an aspect of the present invention, an electromagnetic pump device includes:
a suction check valve including a tubular portion and a flange portion that extends in a radial direction from an end edge of the tubular portion, the suction check valve being formed with a through hole that penetrates the tubular portion and the flange portion to form a suction port in an end surface of the flange portion; and
a strainer attached to the suction port and having a pore forming region which is larger than an inside diameter of the through hole at the tubular portion and in which a large number of pores are formed, in which
the suction check valve is formed with a diameter reducing portion formed such that the inside diameter of the through hole is reduced from the flange portion toward the tubular portion with a degree of diameter reduction varied from a large value to a small value.
The electromagnetic pump device according to the aspect of the present invention includes the suction check valve including the tubular portion and the flange portion which extends in the radial direction from an end edge of the tubular portion, the suction check valve being formed with the through hole which penetrates the tubular portion and the flange portion to form the suction port in an end surface of the flange portion, and the suction check valve is formed with the diameter reducing portion formed such that the inside diameter of the through hole is reduced from the flange portion toward the tubular portion with the degree of diameter reduction varied from a large value to a small value. Thus, the thickness at the boundary portion between the flange portion and the cylindrical portion can be suppressed while an increase in thickness of the flange portion is secured compared to a configuration in which the degree of diameter reduction is constant. In addition, a working fluid can be smoothly sucked through diameter reduction at the diameter reducing portion. As a result, it is possible to allow a working fluid to be smoothly sucked and to provide an electromagnetic pump device with a compact configuration.
In the electromagnetic pump device according to the above aspect of the present invention, the diameter reducing portion may be formed from two stages of tapered surfaces with different inclination angles. With this configuration, the diameter reducing portion can be formed though relatively easy processing. In the electromagnetic pump device according to this aspect of the present invention, in the diameter reducing portion, an inflection point at which the inclination angle of the two stages of tapered surfaces is varied may be determined at a position at which a thickness at a boundary portion between the tubular portion and the flange portion is equal to or more than a predetermined thickness. With this configuration, the thickness of the boundary portion between the flange portion and the cylindrical portion can be more reliably secured.
In the electromagnetic pump device according to the aspect of the present invention, the suction check valve may include a straight portion provided between the end surface of the flange portion and the diameter reducing portion, the straight portion having a uniform diameter corresponding to an inside diameter of the suction port. With this configuration, a working fluid can be sucked more smoothly. In addition, the area of the end surface of the flange portion covered by the strainer can be made relatively large, and thus the pressure of a working fluid applied to the strainer can be received more appropriately.
In the electromagnetic pump device according to the aspect of the present invention, the suction check valve may be formed such that the inside diameter of the suction port is larger than an outside diameter of the tubular portion. Reducing the diameter of such an opening member with a constant degree from a second inside diameter toward a first inside diameter tends to result in a portion in which the thickness is locally significantly reduced. Therefore, the present invention can be applied highly significantly.
In the electromagnetic pump device according to the aspect of the present invention in which a piston moves back and forth within a cylinder to pump a working fluid, the suction check valve may be built in the cylinder. With this configuration, the electromagnetic pump device can be provided with a more compact configuration.
An embodiment of the present invention will be described below.
The solenoid portion 30 includes a solenoid case 31 that is a bottomed cylindrical member, an electromagnetic coil 32, a plunger 34 that serves as a movable element, and a core 36 that serves as a stationary element. The electromagnetic coil 32, the plunger 34, and the core 36 are disposed in the solenoid case 31. In the solenoid portion 30, a current is applied to the electromagnetic coil 32 to form a magnetic circuit in which magnetic flux circulates through the solenoid case 31, the plunger 34, and the core 36, and the plunger 34 is attracted to push out a shaft 38 provided in abutment with the distal end of the plunger 34.
The pump portion 40 is formed as a piston pump that moves a piston 60 back and forth using the electromagnetic force from the solenoid portion 30 and the urging force of a spring 46 to pump working oil. The pump portion 40 includes: a cylinder 50 having a hollow cylindrical shape with its one end joined to the solenoid case 31 of the solenoid portion 30; the piston 60 slidably disposed within the cylinder 50 with its base end surface coaxially abutting against the distal end of the shaft 38 of the solenoid portion 30; the spring 46 that abuts against the distal-end surface of the piston 60 to urge the piston 60 in the direction opposite to the direction in which the electromagnetic force from the solenoid portion 30 is applied; a suction check valve 70 that supports the spring 46 from the side opposite to the distal-end surface of the piston 60, that permits working oil to flow in the direction of being sucked into a pump chamber 56, and that prohibits working oil to flow in the opposite direction; a strainer 90 disposed at the suction port of the suction check valve 70 to trap foreign matter such as dust contained in sucked working oil; a discharge check valve 80 that is built in the piston 60, that permits working oil to flow in the direction of being discharged from the pump chamber 56, and that prohibits working oil to flow in the opposite direction; and a cylinder cover 48 that covers the other end of the cylinder 50 with the piston 60, the discharge check valve 80, the spring 46, and the suction check valve 70 disposed inside the cylinder 50. In the pump portion 40, a suction port 42 is formed at the axial center of the cylinder cover 48, and a discharge port 44 is formed by cutting away a part of the side surface of the cylinder 50 in the circumferential direction.
The piston 60 is formed in a stepped shape with a piston main body 62 having a cylindrical shape, and a shaft portion 64 having a cylindrical shape with its end surface in abutment with the distal end of the shaft 38 of the solenoid portion 30 and being smaller in outside diameter than the piston main body 62. The piston 60 moves back and forth within the cylinder 50 in conjunction with the shaft 38 of the solenoid portion 30. A bottomed hollow portion 62a having a cylindrical shape is formed at the axial center of the piston 60. The discharge check valve 80 is disposed in the hollow portion 62a. The hollow portion 62a extends from the distal-end surface of the piston 60 through the inside of the piston main body 62 to a middle of a space inside the shaft portion 64. The shaft portion 64 is formed with two through holes 64a and 64b that intersect each other at an angle of 90 degrees in the radial direction. The discharge port 44 is formed around the shaft portion 64. The hollow portion 62a communicates with the discharge port 44 via the two through holes 64a and 64b.
The suction check valve 70 includes a valve main body 72 fitted into the cylinder 50 and having a bottomed hollow portion 72a formed inside thereof and a center hole 72b formed at the axial center in the bottom of the hollow portion 72a to communicate between the hollow portion 72a and the pump chamber 56, a ball 74, a spring 76 that provides an urging force to the ball 74, and a plug 78 that serves as a seat portion for the ball 74.
Here, the shape of the plug 78 of the suction check valve 70 will be described in detail.
First,
In the embodiment, in addition, the thus configured diameter reducing portion 79c is implemented by providing the two stages of tapered surfaces 79c1 and 79c2. Thus, the diameter reducing portion 79c can be formed relatively easily without requiring complicated processing. In the embodiment, further, an inflection point P (see
The suction check valve 70 opens with the spring 76 compressed and the ball 74 moved away from the plug 78 when the pressure difference (P1−P2) between the input-side pressure P1 and the output-side pressure P2 is equal to or more than a predetermined pressure to overcome the urging force of the spring 76. The suction check valve 70 closes with the spring 76 expanded and the ball 74 pressed against the tapered portion 79a of the plug 78 to block the through hole 78c when the pressure difference (P1−P2) discussed above is less than the predetermined pressure.
The discharge check valve 80 includes a ball 84, a spring 86 that provides an urging force to the ball 84, and a plug 88 formed as an, annular member with a center hole 89 having an inside diameter that is smaller than the outside diameter of the ball 84.
The discharge check valve 80 opens with the spring 86 compressed and the ball 84 moved away from the center hole 89 of the plug 88 when the pressure difference (P2−P3) between the input-side pressure (pressure on the output side of the suction check valve 70) P2 and the output-side pressure P3 is equal to or more than a predetermined pressure to overcome the urging force of the spring 86. The discharge check valve 80 closes with the spring 86 expanded and the ball 84 pressed against the center hole 89 of the plug 88 to block the center hole 89 when the pressure difference (P2−P3) discussed above is less than the predetermined pressure.
In the cylinder 50, the pump chamber 56 is formed as a space surrounded by an inner wall 51, the distal-end surface of the piston 60, and a surface of the suction check valve 70 on the spring 46 side. When the piston 60 is moved by the urging force of the spring 46, the volume inside the pump chamber 56 is expanded to open the suction check valve 70 and close the discharge check valve 80 to suck working oil via the suction port 42. When the piston 60 is moved by the electromagnetic force of the solenoid portion 30, the volume inside the pump chamber 56 is reduced to close the suction check valve 70 and to open the discharge check valve 80 to discharge the sucked working oil via the discharge port 44.
The cylinder 50 is formed with a step between an inner wall 52, over which the piston main body 62 slides, and an inner wall 54, over which the shaft portion 64 slides. The discharge port 44 is formed at the stepped portion. The stepped portion forms a space surrounded by an annular surface of the stepped portion between the piston main body 62 and the shaft portion 64, and the outer peripheral surface of the shaft portion 64. The space is formed on the opposite side of the piston main body 62 from the pump chamber 56. Thus, the volume of the space is reduced when the volume of the pump chamber 56 is expanded, and expanded when the volume of the pump chamber 56 is reduced. In this event, variations in volume of the space are smaller than variations in volume of the pump chamber 56 because the area (pressure receiving area) over which the piston 60 receives a pressure from the pump chamber 56 side is larger than the area (pressure receiving area) over which the piston 60 receives a pressure from the discharge port 44 side. Therefore, the space serves as a second pump chamber 58. That is, when the piston 60 is moved by the urging force of the spring 46, an amount of working oil corresponding to the amount of expansion in volume of the pump chamber 56 is sucked from the suction port 42 into the pump chamber 56 via the suction check valve 70, and an amount of working oil corresponding to the amount of reduction in volume of the second pump chamber 58 is discharged from the second pump chamber 58 via the discharge port 44. When the piston 60 is moved by the electromagnetic force of the solenoid portion 30, an amount of working oil corresponding to the amount of reduction in volume of the pump chamber 56 is fed from the pump chamber 56 into the second pump chamber 58 via the discharge check valve 80, and an amount of working oil corresponding to the difference between the amount of reduction in volume of the pump chamber 56 and the amount of expansion in volume of the second pump chamber 58 is discharged via the discharge port 44. Thus, working oil is discharged from the discharge port 44 twice while the piston 60 moves back and forth once, which makes it possible to reduce discharge non-uniformities and improve the discharge performance.
In the electromagnetic pump 20 according to the embodiment described above, the suction check valve 70 is formed with the diameter reducing portion 79c formed such that the inside diameter of the through hole 78c is reduced from the flange portion 78b of the plug 78 toward the cylindrical portion 78a with the degree of diameter reduction varied from a large value to a small value. Thus, the thickness T at the boundary portion between the flange portion 78b and the cylindrical portion 78a can be secured while an increase in thickness of the flange portion 78b is suppressed compared to a configuration in which the degree of diameter reduction is constant. In addition, working oil can be smoothly sucked due to diameter reduction at the diameter reducing portion 79c. As a result, working oil can be smoothly sucked and an increase in size of the suction check valve 70 can be prevented, providing the electromagnetic pump 20 with a compact configuration.
In addition, the diameter reducing portion 79c is formed from the two stages of tapered surfaces 79c1 and 79c2, and therefore can be formed through relatively easy processing. Further, the inflection point P that serves as the boundary between the respective inclination angles of the two stages of tapered surfaces 79c1 and 79c2 is determined in such a range that the thickness T at the boundary portion between the cylindrical portion 78a and the flange portion 78b is equal to or more than a predetermined thickness. Thus, the thickness T can be more reliably secured. The straight portion 79b is formed between the end surface 78b1 of the flange portion 78b and the diameter reducing portion 79c. Thus, working oil can be more smoothly sucked, and the pressure of working oil applied to the strainer 90 can be received by the end surface 78b1 more appropriately. In addition, the suction check valve 70 is built in the cylinder 50, providing the electromagnetic pump 20 with a compact configuration.
In the electromagnetic pump 20 according to the embodiment, the diameter reducing portion 79c of the plug 78 of the suction check valve 70 is formed from the two stages of tapered surfaces 79c1 and 79c2. However, the diameter reducing portion 79c may be formed from a plurality of stages, namely three or more stages, of tapered surfaces, or may be formed from a plurality of staircase-like stepped surfaces or rounded curved surfaces in section, rather than tapered surfaces.
In the electromagnetic pump 20 according to the embodiment, the inside diameter D2 is equivalent to the diameter of the pore forming region 92a and larger than the outside diameter of the cylindrical portion 78a. However, the inside diameter D2 may be equivalent to or smaller than the outside diameter of the cylindrical portion 78a.
In the electromagnetic pump 20 according to the embodiment, the straight portion 79b is formed on the plug 78 of the suction check valve 70. However, the straight portion 79b may not be formed.
In the electromagnetic pump 20 according to the embodiment, the suction check valve 70 is built in the cylinder 50. However, a suction check valve may be incorporated in a valve body outside the cylinder 50, rather than being built in the cylinder 50. In this case, the suction check valve may be formed by closing the opening of the cylinder 50 in which the suction check valve 70 is disposed and forming a suction port that leads to the pump chamber, attaching the strainer 90 to the flange portion 78b such that the strainer 90 covers the end surface 78b1 of the plug 78 of the suction check valve 70, and connecting between the suction port of the pump chamber of the cylinder 50 and the output port (corresponding to the center hole 72b in the embodiment) of the suction check valve 70 through an oil passage.
The electromagnetic pump 20 according to the embodiment is configured such that working oil is discharged from the discharge port 44 twice while the piston 60 moves back and forth once. However, the present invention is not limited thereto, and the electromagnetic pump 20 according to the embodiment may be any type of electromagnetic pump, such as a type in which working oil is sucked from the suction port into the pump chamber when the piston is moved forward by the electromagnetic force from the solenoid portion and the working oil in the pump chamber is discharged from the discharge port when the piston is moved backward by the urging force of the spring, and a type in which working oil is sucked from the suction port into the pump chamber when the piston is moved backward by the urging force of the spring and the working oil in the pump chamber is discharged from the discharge port when the piston is moved forward by the electromagnetic force from the solenoid portion.
The electromagnetic pump 20 according to the embodiment is used for a hydraulic control device that hydraulically drives clutches and brakes of an automatic transmission mounted on an automobile. However, the present invention is not limited thereto, and the electromagnetic pump 20 according to the embodiment may be applied to any system that transports fuel, transports a liquid for lubrication, or the like.
Here, the correspondence between the main elements of the embodiment and the main elements of the invention described in the “SUMMARY OF THE INVENTION” section will be described. In the embodiment, the strainer 90 corresponds to the “strainer”. The cylindrical portion 78a of the plug 78 corresponds to the “tubular portion”. The flange portion 78b corresponds to the “flange portion”. The through hole 78c corresponds to the “through hole”. The suction check valve 70 corresponds to the “suction check valve”. The diameter reducing portion 79c corresponds to the “diameter reducing portion”. The correspondence between the main elements of the embodiment and the main elements of the invention described in the “SUMMARY OF THE INVENTION” section does not limit the elements of the invention described in the “SUMMARY OF THE INVENTION” section, because the embodiment is an example given for the purpose of specifically describing the best mode for carrying out the invention described in the “SUMMARY OF THE INVENTION” section. That is, the invention described in the “SUMMARY OF THE INVENTION” section should be construed on the basis of the description in that section, and the embodiment is merely a specific example of the invention described in the “SUMMARY OF THE INVENTION” section.
While a mode for carrying out the present invention has been described above by way of an embodiment, it is a matter of course that the present invention is not limited to the embodiment in any way, and that the present invention may be implemented in various forms without departing from the scope and sprit of the present invention.
The present invention is applicable to the electromagnetic pump device manufacturing industry and so forth.
Number | Date | Country | Kind |
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2011-183147 | Aug 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/068833 | 7/25/2012 | WO | 00 | 12/6/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/027528 | 2/28/2013 | WO | A |
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8414276 | Schuller et al. | Apr 2013 | B2 |
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20090220363 | Schuller | Sep 2009 | A1 |
20110293449 | Shimizu | Dec 2011 | A1 |
20120244022 | Nakai et al. | Sep 2012 | A1 |
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2729362 | Sep 2005 | CN |
853 367 | Oct 1952 | DE |
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A-2006-291914 | Oct 2006 | JP |
A-2011-21593 | Feb 2011 | JP |
2012-202339 | Oct 2012 | JP |
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Number | Date | Country | |
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20140119964 A1 | May 2014 | US |