The disclosure of Japanese Patent Application No. 2017-250286 filed on Dec. 27, 2017, including the specification, drawings and abstract, is incorporated herein by reference in its entirety.
The invention relates to pump apparatuses.
A pump apparatus known in the related art includes a vane pump or a gear pump that functions as a hydraulic pressure supply source to supply a working fluid, such as oil, to a hydraulically operated machine. In one example, the pump apparatus supplies pressurized oil to components of a vehicle, such as a transmission. During this operation, the pump apparatus receives power from a rotational driving force of an engine, for example, so as to pump up oil. The pump apparatus adjusts the pressure of the pumped up oil by, for example, an electromagnetic pressure regulating valve and supplies the resulting oil to components of a vehicle, such as a transmission.
Such a pump apparatus, however, is unable to adjust the pressure of the oil in the event of a malfunction in the pressure regulating valve because the pump apparatus adjusts the pressure of the oil by only the pressure regulating valve. This may result in a situation where the pressure of the oil supplied to the transmission, for example, is higher than necessary, making it impossible to successfully control the transmission.
To cope with such a situation, Japanese Patent Application Publication No. 2016-050505 (JP 2016-050505 A) discloses a pump apparatus that includes a pressure relief valve disposed on a hydraulic line between a vane pump and a pressure regulating valve. Thus, if the pressure of oil becomes higher than necessary, the pressure relief valve would open at a predetermined upper limit pressure value so as to relieve the pressure of the hydraulic line. This accordingly reduces an increase in the pressure of oil to be supplied to a transmission and thus precludes malfunctions in the transmission and the pump apparatus caused by an excessively high pressure. Unfortunately, the pressure relief valve is added to the pump apparatus externally, resulting in an increase in cost. What is now much desired is an inexpensive pump apparatus that includes no external pressure relief valve.
An object of the invention is to provide an inexpensive pump apparatus that incorporates a pressure relief function.
An aspect of the invention provides a pump apparatus including a housing, a shaft, a rotator, a pressure relief passage, and a bearing. The housing includes a suction port and a discharge port. The shaft is rotatably supported in the housing. The rotator is disposed in the housing. The rotator is configured to rotate in accordance with rotation of the shaft so as to transfer hydraulic oil to the discharge port. The hydraulic oil is sucked from the suction port. The pressure relief passage is defined in a portion of the housing facing an outer peripheral surface of the shaft. The pressure relief passage is configured to bring the discharge port into communication with a low pressure region where the hydraulic oil is low in pressure. The bearing is disposed on the pressure relief passage. The bearing supports the shaft such that the shaft is rotatable relative to the housing. When a pressure of the hydraulic oil in the discharge port is lower than a first predetermined pressure, the bearing keeps the pressure relief passage out of communication with an adjacent hydraulic oil passage. When the pressure of the hydraulic oil in the discharge port has increased to reach or exceed the first predetermined pressure, the bearing axially moves relative to the housing so as to bring the pressure relief passage into communication with the adjacent hydraulic oil passage.
The pump apparatus according to this aspect internally includes the pressure relief passage. The bearing is disposed on the pressure relief passage. The bearing is moved so as to bring the pressure relief passage into communication with the adjacent hydraulic oil passage. The bearing thus has not only the function of supporting the shaft but also a pressure relief function. This makes it possible to inexpensively manufacture the pump apparatus having the pressure relief function.
The foregoing and further features and advantages of the invention will become apparent from the following description of example embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
A first embodiment of the invention will be described in detail with reference to
The pump apparatus 1 is housed in a gearbox casing for an automatic transmission of an automobile, for example. The pump apparatus 1 is an oil pump to pump up hydraulic oil stored in an oil pan inside the gearbox casing so as to pressure-feed the hydraulic oil to the components of the transmission.
The pump apparatus 1 includes a housing 10, a side plate 13, a side plate 14, a cam ring 15, a rotor 16, a plurality of vanes 17, a shaft 18, a pressure relief passage 19, a bearing 201, and a bearing 202. The housing 10 includes a first housing 11 and a second housing 12. The side plates 13 and 14 are housed in the housing 10. The shaft 18 transmits a rotational force to the rotor 16. The bearings 201 and 202 are cylindrical sliding bearings. The pressure relief passage 19 and the bearing 202 are components of a pressure relief mechanism RM.
The side plates 13 and 14 and the cam ring 15 are non-rotatable relative to the housing 10. The rotor 16 and the vanes 17 rotate in one direction relative to the housing 10 upon receiving a rotational force transmitted from a driving source through the shaft 18. In the present embodiment, the driving source is an engine of the automobile. The arrow A in
The shaft 18 is rotatably supported in the housing 10. Specifically, the shaft 18 is rotatably supported by the bearing 201 disposed in the first housing 11 and the bearing 202 disposed in the second housing 12. The bearing 201 is press-fitted into a shaft insertion hole 11a defined in the first housing 11. The bearing 202 is press-fitted into a shaft insertion hole 12a defined in the second housing 12. The shaft insertion hole 12a includes a bottom surface 12b illustrated in the right portion of
Each of the bearings 201 and 202 is a cylindrical sliding bearing known in the related alt. The shaft 18 is inserted into the housing 10 and supported by the bearings 201 and 202. An axially central portion of the shaft 18 is coupled to the rotor 16. The left end of the shaft 18 in
In the present embodiment, the axially central portion of the shaft 18 is spline-fitted to the rotor 16 (which is a component of the rotator), so that the rotor 16 and the shaft 18 rotate together. The left end of the shaft 18 in
The first housing 11 and the second housing 12 are arranged along the axis of rotation of the shaft 18. A sheet seal (not illustrated) is interposed between the first housing 11 and the second housing 12. The first housing 11 and the second housing 12 are bolted to each other, with the seal located therebetween.
The first housing 11 defines a housing space 110 in which the side plate 13, the cam ring 15, the rotor 16, and the vanes 17 are housed. The side plate 13 is housed in a portion of the housing space 110 located adjacent to the bottom surface of the first housing 11 (i.e., a portion of the housing space 110 located opposite to the second housing 12).
The cam ring 15 is disposed in a portion of the housing space 110 located closer to an opening of the first housing 11 relative to the side plate 13 in the direction of the axis of the shaft 18. The cam ring 15 is non-rotatably secured to the inside of the housing space 110. The cam ring 15 includes an inner peripheral surface 15a that defines an elliptic cam surface (see
The rotor 16 and the vanes 17 that are components of the rotator are disposed inside the cam ring 15 (i.e., radially inward of the cam ring 15). The rotor 16 is rotatably disposed radially inward of the cam ring 15. The rotor 16 includes an outer peripheral surface 16a, and a plurality of housing grooves 22 (see
As illustrated in
Each of the vanes 17 is thus movable in a radial direction of the rotor 16. An end of each of the vanes 17 protrudes out of the associated housing groove 22 through the outer peripheral surface 16a of the rotor 16. A radially inward end of each housing groove 22 defines a back pressure chamber 23. Each back pressure chamber 23 receives a pressure for radially outwardly pushing the associated vane 17.
As illustrated in
A circumferential space Ar1 is defined inside the cam ring 15 (i.e., radially inward of the cam ring 15). Specifically, the circumferential space Ar1 is defined between the inner peripheral surface 15a of the cam ring 15 and the outer peripheral surface 16a of the rotor 16. The circumferential space Ar1 is divided into a plurality of pump chambers 50 each defined by an associated pair of the vanes 17 adjacent to each other in the circumferential direction of the rotor 16. In the present embodiment, the pump apparatus 1 includes ten vanes 17 that rotate together with the rotor 16. Thus, ten pump chambers 50 are defined inside the cam ring 15.
As illustrated in
The hydraulic oil compressed in the pump chambers 50 and discharged to the discharge ports 113 by rotation of the rotor 16 is supplied to a hydraulic line (not illustrated) of the transmission. The pressure of the hydraulic oil supplied to the hydraulic line (not illustrated) is adjusted to a predetermined pressure P1 by an electromagnetic pressure regulating valve (not illustrated) disposed outside the pump apparatus 1. In one example, the predetermined pressure P1 is in the range of 1 MPa to 5 MPa. As a result of this pressure adjustment, the pressure of the hydraulic oil in the discharge ports 113 connected to the hydraulic line is also adjusted to the pressure P1. The hydraulic oil in the hydraulic line (not illustrated), whose pressure has been adjusted to the pressure P1, activates actuators of the transmission.
The second housing 12 includes suction ports 121 and the pressure relief mechanism RM. The suction ports 121 are in communication with a low pressure region. The suction ports 121 suck low pressure hydraulic oil stored in an oil tank (not illustrated). The pressure of the low pressure hydraulic oil corresponds to the atmospheric pressure P0. In the present embodiment, the second housing 12 includes the suction ports 121 provided at two locations (see the dashed lines 121 in
The suction ports 121 are in communication with an inlet (not illustrated) of the second housing 12. The inlet is configured to be in communication with a reservoir of the oil pan inside the gearbox casing so as to suck the hydraulic oil stored in the reservoir.
As illustrated in
Subsequently, the predetermined ones of the pump chambers 50 further rotate in the direction A, approach the discharge ports 113, and then gradually decrease in volume. Thus, the hydraulic oil in the pump chambers 50 approaches the discharge ports 113 while being compressed, and is then discharged to the discharge ports 113.
As described above, the rotation of the rotor 16 and the vanes 17 compresses the hydraulic oil in a low pressure state (i.e., an atmospheric pressure state) sucked from the suction ports 121 (which are in communication with the low pressure region), increases the pressure of the hydraulic oil, and then transfers the resulting hydraulic oil to the discharge ports 113. As previously mentioned, the pressure regulating valve on the hydraulic line connected to the discharge ports 113 is controlled so as to adjust the pressure of the hydraulic oil in the discharge ports 113 to the pressure P1. The amount of hydraulic oil flowing into the discharge ports 113 increases or decreases in proportion to the rotational speed of the rotor 16.
As a result of this pressure adjustment, a pressure equal to or substantially equal to the pressure P1 in the discharge ports 113 is applied to the back pressure chambers 23 of the rotor 16 and the back pressure groove 24 of the side plate 14 in communication with the back pressure chambers 23. As illustrated in
As illustrated in
The hydraulic oil flows to the passages C to F from the back pressure groove 24. A relatively large pressure P2 caused by the hydraulic oil is thus applied to an end face 202a of the bearing 202 located adjacent to the passage E. The pressure P2 of the hydraulic oil applied to the end face 202a, however, is normally smaller than the pressure P1 in the discharge ports 113. The pressure P1 in the discharge ports 113 is equal to the pressure P1 in the back pressure groove 24. The relationship between the pressure P2 and the pressure P1 is represented as P2<P1. Of the passages C to F, the passage F has the smallest cross-sectional area. The passage F thus functions as a throttle.
The structure of the pressure relief mechanism RM will be described below with reference to
As illustrated in
As previously mentioned, the pressure in the discharge ports 113 is equal to or substantially equal to the pressure in the back pressure chambers 23 of the rotor 16 and the pressure in the back pressure groove 24 in communication with the back pressure chambers 23. Passages C′ to F′ similar to the passages C to F are defined in a portion of the pump apparatus 1 located in the left portion of
The pressure relief passage 19 is a passage (i.e., a hole) defined in a circumferential portion of the second housing 12 adjacent to an inner peripheral surface 12a1 of the shaft insertion hole 12a. In the present embodiment, the pressure relief passage 19 is disposed at a single location. Specifically, the process of defining the pressure relief passage 19 involves making a hole in the portion of the second housing 12 by moving, for example, a drill in a direction Gin
The bearing 202 is disposed on the pressure relief passage 19. As illustrated in
Suppose that the distance between the bottom surface 12b of the shaft insertion hole 12a and an end face 202b of the bearing 202 located opposite to the end face 202a along the axis of the shaft 18 is a distance L3. In this case, the length L1, the distance L2, and the distance L3 have the following relationship: L3>(L2−L1). The load F1, the distance L2, and the distance L3 will be described in more detail below.
The following description describes how the pump apparatus 1 having the above-described structure operates and how the length L1, the distance L2, and the distance L3 related to the placement of the pressure relief mechanism RM are set. The engine supplies a driving force to the shaft 18 of the pump apparatus 1 through the sprocket so as to rotate the shaft 18. The rotation of the shaft 18 rotates the rotor 16 inside the cam ring 15. In a suction step, the rotation of the rotor 16 causes the predetermined ones of the pump chambers 50, deviated from each other by 180 degrees, to increase in volume, so that the hydraulic oil is sucked into the predetermined ones of the pump chambers 50 from the suction ports 121.
In a compression step, further rotation of the rotor 16 gradually reduces the volume of the predetermined ones of the pump chambers 50 and compresses the oil sucked into the predetermined ones of the pump chambers 50. Then, the predetermined ones of the pump chambers 50 further decrease in volume in a discharge step. In the discharge step, the hydraulic oil is supplied from the predetermined ones of the pump chambers 50 to the discharge ports 113 defined in the side plate 13 and the first housing 11 (which is a component of the housing 10).
The hydraulic oil supplied to the discharge ports 113 is then supplied to the hydraulic line (not illustrated) of the transmission. The pressure of the hydraulic oil supplied to the hydraulic line (not illustrated) is adjusted to the predetermined pressure P1 by the electromagnetic pressure regulating valve (not illustrated) disposed outside the pump apparatus 1. In one example, the pressure P1 is in the range of 1 MPa to 5 MPa. The present embodiment is described on the assumption that the pressure P1 is 5 MPa. Under normal conditions, the hydraulic oil whose pressure has been adjusted to the pressure P1 (5 MPa) makes it possible to successfully control the actuators of the transmission (see the range “NORMAL OPERATION” illustrated in the graph of
The pressure regulating valve on the hydraulic line, however, may malfunction and fail to make a pressure adjustment. In such a case, the pressure P1 of the hydraulic oil in the discharge ports 113 may considerably exceed a pressure suitable for control of the transmission, resulting in an excessive pressure PNG. In one example, the pressure suitable for control of the transmission is 5 MPa, and the excessive pressure PNG is 30 MPa or more. The excessive pressure PNG may cause defective conditions, such as deformation of component(s) on the hydraulic line of the transmission and/or component(s) of the pump apparatus 1. This may make it impossible for the pump apparatus 1 and/or the transmission to perform intended functions.
To solve this problem, the present embodiment involves activating the pressure relief mechanism RM at a time R if the pressure (discharge pressure) P1 in the discharge ports 113 has exceeded the pressure suitable for normal control of the transmission. The pressure suitable for normal control of the transmission may be 5 MPa. In
In the present embodiment, the area S1 is set such that the pressure (discharge pressure) in the discharge ports 113 is prevented from exceeding the excessive pressure PNG (30 MPa) and the actuators of the transmission are controllable. A method for setting the area S1 will be described below.
In one example, the minimum pressure in the discharge ports 113 that enables control of the actuators on the hydraulic line is 1 MPa (see
In actuality, with the aim of enabling the pressure relief mechanism RM to perform the above-described operations, an experiment is conducted so as to determine the correlation between the pressure P1 of the hydraulic oil in the discharge ports 113 and the pressure P2 of the hydraulic oil in the passage E associated with the pressure P1. Then, the first predetermined pressure P3 of the hydraulic oil in the discharge ports 113 is set at 25 MPa, for example. A pressure P21 of the hydraulic oil in the passage E associated with the first predetermined pressure P3 (25 MPa) is determined on the basis of the result of the experiment. In one example, the pressure P21 is 7 MPa.
The first predetermined pressure P3 is 30 MPa or less and preferably as close as possible to 30 MPa. If the first predetermined pressure P3 is too close to 30 MPa, however, operating variations of the pressure relief mechanism RM may cause the pressure P1 of the hydraulic oil in the discharge ports 113 to exceed 30 MPa. By way of example, the present embodiment thus involves setting the first predetermined pressure P3 at 25 MPa in consideration of operating variations of the pressure relief mechanism RM.
An increase in the pressure P1 in the discharge ports 113 may activate the pressure relief mechanism RM, and then the engine speed, for example, may decrease, resulting in a reduction in the number of rotations of the shaft 18 of the pump apparatus 1. If such a situation occurs, setting the first predetermined pressure P3 at 25 MPa would make it likely that the pressure P1 of the hydraulic oil in the discharge ports 113 will be maintained at or above 1 MPa corresponding to the second predetermined pressure P4. This process is described by way of example only. The first predetermined pressure P3 may be higher or lower than 25 MPa.
To enable the pressure relief mechanism RM to perform the above-described operations, the area S1 by which the pressure relief passage 19 is to be in communication with the passage E is set in accordance with the pressure P21 of the hydraulic oil in the passage E. Specifically, the present embodiment involves calculating the area S1 that causes the hydraulic oil, whose pressure is the pressure P21 in the passage E, to flow into the pressure relief passage 19, so that the pressure P1 in the discharge ports 113 equivalent to the first predetermined pressure P3 (which may be 25 MPa) is reduced to, for example, about 7 MPa as illustrated in the graph of
As illustrated in the graph of
The length L1 of the pressure relief passage 19 between the bottom surface 12b of the shaft insertion hole 12a and the end 19b of the pressure relief passage 19 and the distance L2 between the bottom surface 12b and the end face 202a of the bearing 202 are set such that the pressure relief passage 19 is brought into communication with the passage E by the area S1 calculated.
The load F1 by which the bearing 202 is to be press-fitted to the inner peripheral surface 12a1 of the shaft insertion hole 12a is set such that the bearing 202 axially moves by the distance L3 when the end face 202a of the bearing 202 receives the pressure P21 of the hydraulic oil in the passage E associated with the first predetermined pressure P3 (which may be 25 MPa).
The load F1 is calculated by Eq. (1), where S2 denotes the area of the end face 202a of the bearing 202, and P21 denotes the pressure of the hydraulic oil in the passage E.
F1=P21×S2. . .Eq. (1)
Alternatively, the load F1 may be calculated by repeatedly conducting experiments instead of using Eq. (1).
When the pressure P1 of the hydraulic oil in the discharge ports 113 is lower than the first predetermined pressure P3, the bearing 202 keeps the pressure relief passage 19 out of communication with the passage E as illustrated in
The electromagnetic pressure regulating valve (not illustrated) on the hydraulic line of the transmission may malfunction and fail to make a pressure adjustment, causing the pressure P1 of the hydraulic oil in the discharge ports 113 to reach or exceed the first predetermined pressure P3. In such a case, at least the pressure P21 associated with the first predetermined pressure P3 is applied to the end face 202a of the bearing 202. Upon receiving the pressure P21 on the end face 202a, the bearing 202 is urged rightward along its axis and thus moved relative to the second housing 12 (which is a component of the housing 10) by the distance L3 (see
The length L1, the distance L2, and the distance L3 have the following relationship: L3>(L2−L1). The axial movement of the bearing 202 by the distance L3 brings the pressure relief passage 19 into communication with the passage E by the area S1. The hydraulic oil in the discharge ports 113 then flows into the gearbox casing (i.e., the low pressure region) through the back pressure chambers 23, the back pressure groove 24, the passage C, the passage D, the passage E, and the pressure relief passage 19.
The pressure P1 of the hydraulic oil in the discharge ports 113 and the pressure in the hydraulic line of the transmission connected to the discharge ports 113 thus fall between the first predetermined pressure P3 (which may be 25 MPa) and the second predetermined pressure P4 (which may be 1 MPa). Alternatively, no second predetermined pressure P4 may be set, and the pressure P1 in the discharge ports 113 may be reduced to the atmospheric pressure. Such an alternative embodiment prevents at least deformation of component(s) on the hydraulic line of the transmission and component(s) of the pump apparatus 1 or damage to component(s) on the hydraulic line of the transmission and component(s) of the pump apparatus 1.
In the first embodiment, the pump apparatus 1 includes the rotor 16 and the vanes 17 (which are components of the rotator) disposed in the housing 10. The rotor 16 and the vanes 17 rotate in accordance with rotation of the shaft 18 so as to increase the pressure of the low pressure hydraulic oil sucked from the suction ports 121 and transport the resulting hydraulic oil to the discharge ports 113. The pump apparatus 1 includes the pressure relief passage 19 defined in a portion of the second housing 12 (which is a component of the housing 10) facing the outer peripheral surface 18a of the shaft 18. The pressure relief passage 19 is configured to bring the discharge ports 113 into communication with the low pressure region where the pressure of the hydraulic oil is low.
The pump apparatus 1 includes the bearing 202 disposed on the pressure relief passage 19. The bearing 202 supports the shaft 18 such that the shaft 18 is rotatable relative to the second housing 12. When the pressure P1 of the hydraulic oil in the discharge ports 113 is lower than the first predetermined pressure P3, the bearing 202 keeps the pressure relief passage 19 out of communication with the passage E. When the pressure P1 of the hydraulic oil in the discharge ports 113 is increased to reach or exceed the first predetermined pressure P3, the bearing 202 axially moves relative to the housing 10 so as to bring the pressure relief passage 19 into communication with the passage E.
In the first embodiment, the pressure relief passage 19 is disposed not outside but inside the pump apparatus 1. The bearing 202 is disposed on the pressure relief passage 19 and moved axially so as to bring the pressure relief passage 19 into communication with the passage E. The bearing 202 thus has not only the function of supporting the shaft 18 but also the pressure relief function. This makes it possible to inexpensively manufacture the pump apparatus 1 having the pressure relief function.
In the first embodiment, the pressure relief passage 19 is defined in a portion of the second housing 12 (which is a component of the housing 10) adjacent to the inner peripheral surface 12a1 of the shaft insertion hole 12a. The bearing 202 is attached to the inner peripheral surface 12a1 of the shaft insertion hole 12a. This enables a normal bearing structure to function as a pressure relief mechanism by merely defining the pressure relief passage 19 in the portion of the second housing 12 adjacent to the inner peripheral surface 12a1 of the shaft insertion hole 12a. Consequently, the first embodiment significantly facilitates the manufacture of the pump apparatus 1 having the pressure relief function and thus considerably reduces the manufacturing cost of the pump apparatus 1.
The first embodiment involves activating the pressure relief mechanism RM so as to bring the pressure relief passage 19 into communication with the passage E when the pressure P1 of the hydraulic oil in the discharge ports 113 has increased to reach or exceed the first predetermined pressure P3. This causes the hydraulic oil in the discharge ports 113 to flow into the pressure relief passage 19 through the passage C extending along a lateral surface of the rotor 16 that is a component of the rotator. Thus, the passage C extending along the lateral surface of the rotor 16 included in the pump apparatus 1 is used as a passage for the pressure relief function. This makes it possible to inexpensively provide the pressure relief mechanism RM.
In the first embodiment, the bearing 202 of the pressure relief mechanism RM axially moves by the distance L3 so as to bring the pressure relief passage 19 into communication with the passage E when the pressure P1 of the hydraulic oil in the discharge ports 113 has increased to reach or exceed the first predetermined pressure P3. The distance L3 is set such that the pressure P1 of the hydraulic oil in the discharge ports 113 falls between the first predetermined pressure P3 and the second predetermined pressure P4 lower than the first predetermined pressure P3.
In the first embodiment, the second predetermined pressure P4 is set at a level that enables activation of the actuators of the transmission so as to allow the vehicle to keep running. Thus, if the pressure P1 of the hydraulic oil in the discharge ports 113 has increased to reach or exceed the first predetermined pressure P3 and activated the pressure relief mechanism RM, the vehicle would keep running, giving a driver sufficient time to move the vehicle to a safe place.
In the first embodiment, the low pressure region is located in the atmospheric pressure space outside the pump apparatus 1. Specifically, the low pressure region is an inner space of the gearbox casing where the hydraulic oil is stored. Thus, the pump apparatus 1 to be attached to the inside of the gearbox casing is provided at a low cost, because the outlet of the pressure relief passage 19 does not have to be provided with any special passage.
In the first embodiment, the pump apparatus 1 includes the cam ring 15 non-rotatably secured to an inner portion of the housing 10. The cam ring 15 includes the inner peripheral surface 15a that defines the cam surface. The pump apparatus 1 includes the rotor 16 and the vanes 17 that are components of the rotator. The rotor 16 is rotatably disposed radially inward of the cam ring 15. The rotor 16 includes the housing grooves 22 and the back pressure chambers 23. The housing grooves 22 extend radially inward from the outer peripheral surface 16a of the rotor 16. The back pressure chambers 23 are each defined in the radially inward end of an associated one of the housing grooves 22. The back pressure chambers 23 are in communication with the discharge ports 113. The vanes 17 are each slidably housed in an associated one of the housing grooves 22. The vanes 17 divide the circumferential space Ar1 between the cam surface and the outer peripheral surface 16a of the rotor 16 into the pump chambers 50.
When the pressure P1 of the hydraulic oil in the discharge ports 113 has increased to reach or exceed the first predetermined pressure P3, the bearing 202 axially moves so as to bring the pressure relief passage 19 into communication with the passage E. In this case, the hydraulic oil stored in the back pressure chambers 23 flows along the lateral surface of the rotor 16 and then flows into the pressure relief passage 19. The pump apparatus 1 thus functions as a vane pump. Because the distance between the shaft 18 and each back pressure chamber 23 of the rotor 16 is short, the hydraulic oil in the back pressure chambers 23 is likely to flow along the lateral surface of the rotor 16 and the outer peripheral surface 18a of the shaft 18 and then flow out of the pump apparatus 1. The pump apparatus 1 according to the first embodiment of the invention includes the pressure relief mechanism RM that includes the bearing 202 disposed radially outward of the shaft 18. The first embodiment involves moving the bearing 202 of the pressure relief mechanism RM by effectively using the pressure of the hydraulic oil that flows along the lateral surface of the rotor 16 and the outer peripheral surface 18a of the shaft 18 and then flows out of the pump apparatus 1. Activating the pressure relief mechanism RM including the bearing 202 effectively reduces the pressure in the discharge ports 113.
In the first embodiment, the pressure relief mechanism RM is disposed in the second housing 12 located in the right portion of the pump apparatus 1 in
In the first embodiment, the bottom surface 12b functions as a stopper to restrict rightward movement of the bearing 202 along its axis. In the first variation, the pump apparatus 1 includes a stopper 121b to restrict leftward movement of the bearing 201 along its axis. As illustrated in
The pressure relief mechanism RM according to the first embodiment includes: the pressure relief passage 19 defined in a portion of the second housing 12 (which is a component of the housing 10) adjacent to the inner peripheral surface 12a1 of the shaft insertion hole 12a; and the bearing 202 attached to the inner peripheral surface 12a1 of the shaft insertion hole 12a. The invention, however, is not limited to this embodiment.
A second embodiment of the invention will be described below with reference to
Each of the pump apparatus 1 according to the first embodiment and the pump apparatus 101 according to the second embodiment is a vane pump. Alternatively, each of the pump apparatuses 1 and 101 may be any other type of pump. In one example, each of the pump apparatuses 1 and 101 may be a known gear pump. In this case, the pressure relief mechanism RM may be disposed between a shaft to rotate a gear and a housing supporting the shaft in a manner similar to that described in the foregoing embodiments. A gear pump usually transfers hydraulic oil by an outer peripheral portion of the gear. The outer peripheral portion of the gear will be referred to as a “hydraulic oil transferring portion”. The distance between the hydraulic oil transferring portion and the shaft is long in a radial direction. This reduces the amount and pressure of the hydraulic oil that flows into the pressure relief mechanism RM from the hydraulic oil transferring portion along an end face of the gear. The pump apparatus 1 or 101 that is a gear pump, however, is reasonably cost effective.
The foregoing embodiments have been described on the assumption that each of the pump apparatuses 1 and 101 is an oil pump apparatus for a transmission by way of example only. Each of the pump apparatuses 1 and 101 may be used as an oil pump to supply hydraulic pressure to various hydraulically operated machines, such as a steering system and a machine tool.
Number | Date | Country | Kind |
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JP2017-250286 | Dec 2017 | JP | national |
Number | Name | Date | Kind |
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Number | Date | Country |
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2016-50505 | Apr 2016 | JP |
Entry |
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Extended European Search Report dated Mar. 26, 2019 in Patent Application No. 18215089.6, 5 pages. |
Number | Date | Country | |
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20190195223 A1 | Jun 2019 | US |