The present invention especially relates to a hydraulic apparatus used in an automatic transmission of a vehicle.
As the hydraulic apparatus, there is a radial piston pump for sucking operation fluid and discharging the same to supply to a required portion, for example, and this is disclosed in a following patent document 1. In the radial piston pump disclosed in the patent document 1, a valve shaft having a suction port, a discharge port, a suction slot and a discharge slot is provided in a housing, a rotor is supported so as to be rotatable relative to the valve shaft, a cam ring is rotatably provided on an outer side of the rotor, a cylinder is radially provided on the rotor, and a piston is slidably mounted on the cylinder, thereby forming a pump chamber for selectively communicating with the suction slot and the discharge slot. Therefore, the operation fluid is sucked from the suction port through the suction slot into the pump chamber, and discharged through the discharge slot to the discharge port.
There is a case in which such radial piston pump is incorporated in the automatic transmission of the vehicle, the rotor of the radial piston pump is coupled to one of an input shaft and an output shaft, the cam ring of the radial piston pump is coupled to the other of the input shaft and the output shaft, to be used as an oil pump for discharging the oil according to difference in rotational speed between the input shaft and the output shaft, that is to say, a differential oil pump. In this case, at the time of positive driving such as when accelerating the vehicle, that is to say, when the rotational speed of the input shaft is higher than that of the output shaft and the input shaft relatively positively rotates, the radial piston pump can operate to discharge the operation fluid. However, at the time of being driven in which an engine brake acts on the vehicle, that is to say, when the rotational speed of the input shaft is lower than that of the output shaft and the input shaft relatively negatively rotates, a suction stroke and a discharge stroke of the operation fluid by the piston are inverted and the radial piston pump cannot discharge the operation fluid.
Therefore, in a following patent document 2, for example, a check valve is used to be able to appropriately discharge the operation oil at positive rotation and negative rotation of the input shaft. That is to say, in the oil pump of the patent document 2, a suction opening of the oil pump is connected to a liquid retaining unit through a first check valve and a discharge opening of the oil pump is connected to a discharge liquid requiring unit through a second check valve, and the discharge opening of the oil pump is connected to the liquid retaining unit through a third check valve and the suction opening of the oil pump is connected to the discharge liquid requiring unit through a fourth check valve, and it is arranged such that when the oil pump positively rotates, only the first and second check valves are opened, and when the oil pump negatively rotates, only the third and fourth check valves are opened. Therefore, the oil pump can discharge a predetermined flow amount regardless of a rotational direction of the motor.
In the conventional oil pump disclosed in the above-described patent document 2, a plurality of check valves are provided on the suction opening and the discharge opening of the oil pump, so that the oil can be discharged regardless of the rotational direction of the motor by opening the one group of check valves when the oil pump positively rotates and opening the other group of check valves when the oil pump negatively rotates. However, the check valve is for releasing a pressure of the oil when this is higher than a predetermined pressure, so that pressure loss of the oil is large and cavitation and operational inadequacy of the piston (cam nose jumping phenomenon) easily occur when sucking the oil, and further, there is a problem that mechanical efficiency deteriorates.
In addition, although the differential oil pump is for sucking to discharge the oil as the operation fluid according to the rotational speeds of two rotating bodies, it is desirable that this is used as the motor for obtaining power by rotating one rotating body by supplying the oil while restraining the other rotating body. However, in the above-described conventional oil pump, a plurality of check valves are provided on the suction opening and the discharge opening of the oil pump, so that it is difficult to allow the same to serve as the motor.
Patent Document 1: Japanese Patent Application Laid-open No. 02-108866
Patent Document 2: Japanese Patent Application Laid-open No. 09-303256
An object of the present invention is to provide the hydraulic apparatus, which improve the mechanical efficiency and versatility by efficiently supplying the fluid regardless of the rotational direction of the rotating member.
A hydraulic apparatus according to the present invention includes a first rotating member and a second rotating member provided so as to be relatively rotatable with a central axis; a cam provided on the first rotating member; a piston provided on the second rotating member so as to be opposed to the cam and movable along a radial direction; a pressing unit that presses the piston against the cam to contact; a fluid chamber provided on the second rotating member, the chamber having a volume expanded and contracted according to a movement of the piston; a first fluid path and a second fluid path through which fluid flows into or out from the fluid chamber; and a path switching device that switches an inflow direction and an outflow direction of the fluid in the first fluid path and the second fluid path according to difference in pressure between the first fluid path and the second fluid path.
According to one aspect of the embodiment, it is preferable that the path switching device has a moving body that switches the inflow direction and the outflow direction of the fluid in the first fluid path and the second fluid path by moving according to the difference in pressure between the first fluid path and the second fluid path.
According to one aspect of the embodiment, it is preferable that the moving body is movable to a first movement position for setting the first fluid path to the outflow direction of the fluid and switching the second fluid path to the inflow direction of the fluid, and to a second movement position for setting the first fluid path to the inflow direction of the fluid and switching the second fluid path to the outflow direction of the fluid, and the moving body is biasingly supported at the first movement position by a biasing unit.
According to one aspect of the embodiment, it is preferable that an input shaft is coupled to the first rotating member and the input shaft is coupled to the second rotating member, and the biasing unit biasingly supports the moving body such that a pressure in the first fluid path or the second fluid path communicating with a fluid supplying unit becomes higher when a rotational speed of the first rotating member is higher than the rotational speed of the second rotating member.
According to one aspect of the embodiment, it is preferable that the path switching device includes: a housing; a first port and a second port provided in the housing with which the first fluid path and the second fluid path communicate, respectively; a suction port and an exhaust port provided in the housing with which a fluid suction path and a fluid exhaust path communicate; a spool movably supported in the housing that switches a communication relationship between the first port and the second port and the suction port and the exhaust port; a first pressure port provided in the housing with which a pressure in the first fluid path acts on the spool; and a second pressure port provided in the housing with which the pressure in the second fluid path acts on the spool.
According to one aspect of the embodiment, it is preferable that the path switching device includes: a rotating body concentrically and rotatably supported inside the second rotating member; a suction chamber provided on the rotating body with which a fluid suction path communicates and the first fluid path or the second fluid path can communicate; an exhaust chamber provided on the rotating body with which a fluid exhaust path communicates and the first fluid path or the second fluid path can communicate; a first pressure chamber rotatable by the pressure in the first fluid path acting on the rotating body; and a second pressure chamber rotatable by the pressure in the second fluid path acting on the rotating body, and wherein the path switching device is capable of switching a communication relationship between the first fluid path and the second fluid path and the suction chamber and the exhaust chamber according to a rotational position of the rotating body.
According to one aspect of the embodiment, it is preferable that the path switching device is coupled to a fluid retaining unit through the fluid suction path and is coupled to the fluid supplying unit through the fluid exhaust path, and a control valve that controls a flow amount of the fluid is provided at least one of the fluid suction path and the fluid exhaust path.
According to one aspect of the embodiment, it is preferable that the input shaft is coupled to one of the first rotating member and the second rotating member and an output shaft is coupled to the other of the first rotating member and the second rotating member, the piston reciprocates according to difference in rotational speed between the first rotating member and the second rotating member, and the fluid is sucked and discharged through the first fluid path and the second fluid path by varying pressure in the fluid chamber.
According to one aspect of the embodiment, it is preferable that the hydraulic apparatus further includes a restraining unit capable of restraining the first rotating member or the second rotating member, and a fluid supplying unit capable of supplying the fluid in the first fluid path or the second fluid path.
According to the hydraulic apparatus of the present invention, it is possible to efficiently supply the fluid regardless of the rotational direction of the rotating member to improve the mechanical efficiency and improve the versatility.
The present invention relates to a hydraulic apparatus used in an automatic transmission of a vehicle, and can be used as a pump, a power transmission device and a motor. The pump is capable of sucking fluid therein and discharging the same to outside by allowing a piston to reciprocate along a cam shape by relatively rotating first and second rotating members. The power transmission device transmits power to the first or second rotating member, and by relatively rotating the first and second rotating members, this allows the piston to reciprocate along the cam shape, and can transmit the power between the first and second rotating members by engaging force of the piston and the cam. The motor supplies the fluid therein and exhausts the same to outside to operate the piston, thereby relatively rotating the first and second rotating members by the engaging force of the piston and the cam to take out the power.
Preferably, relatively rotatable first and second rotating members are provided, the cam is provided on the first rotating member, the piston opposed to the cam and movable in a radial direction is provided on the second rotating member and the piston is pressed against the cam to contact by a pressing unit, a fluid chamber of which volume is expanded and contracted according to a movement of the piston is provided on the second rotating member, first and second fluid paths through which the fluid flows into or out from the fluid chamber are provided, and a path switching device for switching an inflow direction and an outflow direction of the fluid according to difference in pressure between the first and second fluid paths is provided. According to this, the path switching device switches the inflow direction and the outflow direction of the fluid according to the difference in pressure between the first and second fluid paths, so that the fluid can be supplied to a predetermined oil passage regardless of a rotational direction of the rotating member and moreover mechanical efficiency can be improved, and by allowing the same to serve as a device for taking out the power, versatility thereof can be improved.
Preferably, the path switching device has a moving body, which moves according to the difference in pressure between the first and second fluid paths, to switch the inflow direction and the outflow direction of the fluid in the first and second fluid paths. According to this, it is possible to switch the inflow direction and the outflow direction of the fluid in each fluid path by moving the moving body according to the difference in pressure between the first and second fluid paths, and the fluid can be appropriately sucked and discharged with a simple structure.
Preferably, the moving body is movable to a first movement position for setting the first fluid path to the outflow direction of the fluid and switching the second fluid path to the outflow direction of the fluid, and to a second movement position for setting the first fluid path to the inflow direction of the fluid and switching the second flow path to the outflow direction of the fluid, and is biasingly supported at the first movement position by biasing means. According to this, the inflow direction of the oil and the outflow direction of the oil can be switched by moving the moving body to the first and second movement positions according to the difference in pressure between the first and second fluid paths, and the oil can be sucked and discharged with the simple structure and by simple operation.
Preferably, an input shaft is coupled to the first rotating member and the input shaft is coupled to the second rotating member, and the biasing means biasingly supports the moving body such that pressure in the first fluid path or the second fluid path, which communicates with a fluid supplying unit, becomes high when the rotational speed of the first rotating member is higher than that of the second rotating member. According to this, the moving body is biasingly supported by the biasing means, so that a backflow of the fluid can be prevented at the time of start and the fluid can be discharged at an early stage, and also the simple structure can be obtained.
Preferably, the path switching device has a housing, a first port and a second port provided in the housing with which the first and second fluid paths communicate, respectively, suction and exhaust ports provided in the housing with which a fluid suction path and a fluid exhaust path communicate, respectively, a spool movably supported in the housing for switching a communication relationship between the first and second ports and the suction and exhaust ports, a first pressure port provided in the housing in which the pressure in the first fluid path acts on the spool, and a second pressure port provided in the housing with which the pressure in the second fluid path acts on the spool. According to this, by allowing oil pressures in the first and second fluid paths to act on the spool through each pressure port, the spool is moved to the first movement position or the second movement position according to the difference in pressure therebetween, and the communication relationship between the first and second ports and the suction and exhaust ports can be switched by the movement of the spool, so that the fluid can be appropriately sucked and discharged.
Preferably, the path switching device has a rotating body concentrically rotatably supported inside the second rotating member, a suction chamber provided on the rotating body with which the fluid suction path communicates and the first fluid path or the second fluid path can communicate, an exhaust chamber provided on the rotating body with which the exhaust path communicates and the first fluid path or the second fluid path can communicate, a first pressure chamber rotatable by the pressure in the first fluid path acting on the rotating body, and a second pressure chamber rotatable by the pressure in the second fluid path acting on the rotating body, and is capable of switching the communication relationship between the first and second fluid paths and the suction and exhaust chambers according to a rotational position of the rotating body. According to this, a smaller device can be obtained due to improved space efficiency, and a large opening area of the oil passage can be ensured, so that pressure loss can be further suppressed, and since the rotating body is rotatable relative to the second rotating member, operational inadequacy can be prevented.
Preferably, the path switching device is coupled to a fluid retaining unit through the fluid suction path and is coupled to the fluid supplying unit through the fluid exhaust path, and a control valve for controlling a flow amount of the fluid is provided at least one of the fluid suction path and the fluid exhaust path. According to this, by controlling the flow amount of the fluid to one of the fluid suction path and the fluid exhaust path by the control valve, a torque transmission amount between the first and second rotating members can be adjusted, so that the oil can be appropriately sucked and exhausted, and the torque can be appropriately transmitted between the first and second rotating members.
Preferably, the input shaft is coupled to one of the first and second rotating members and an output shaft is coupled to the other of them, the piston reciprocates by the difference in rotational speed between the first and second rotating members and the pressure in the fluid chamber changes, thereby, the fluid is sucked and discharged through the first and second fluid paths. According to this, an appropriate discharge amount of the oil can be ensured based on the difference in rotational speed between the first and second rotating members.
Preferably, restraining means capable of restraining the first or second rotating member and fluid supplying means capable of supplying the fluid to the first or second fluid path are provided. According to this, by supplying the fluid to the first or second fluid path by the fluid supplying means to rotate in a state in which the first or second rotating member is restrained by the restraining means, this can serve as the motor.
Hereinafter, embodiments of the hydraulic apparatus according to the present invention are described in detail with reference to drawings. Meanwhile, the present invention is not limited by the embodiments.
In the drive transmission system of the vehicle to which the hydraulic apparatus of the first embodiment is applied, as shown in
On the input shaft 14, a primary shaft 15 is supported on an outer peripheral side thereof so as to be relatively rotatable through a plurality of bearings 16a, 16b, 16c and 16d. The input shaft 14 and the primary shaft 15 are arranged in a casing 17. The casing 17 is composed of a front case 18, a center case 19 and a rear case 20 joined to be fixed by a coupling bolt not shown. Continuous partition walls 18a, 19a, 20a and 20b are provided on inner surfaces of the front case 18, the center case 19 and the rear case 20, and the primary shaft 15 is rotatably supported on the partition walls 18a, 19a, 20a and 20b through bearings 21a, 21b and 21c.
A first accommodating chamber A1 is formed inside the casing 17 in a space enclosed by the partition walls 20a and 20b of the rear case 20. An oil pump 22 as the hydraulic apparatus of this embodiment is provided in the first accommodating chamber A1. The oil pump 22 is a radial piston pump.
In the oil pump 22, as shown in
Also, a rotary valve 27 is joined to the rotating plate 24, and an end plate 28 integrally formed on an end portion of the input shaft 14 fits an outer peripheral surface of the rotary valve 27 to be integrally joined.
In the rotary valve 27, a first communication hole 29 is formed from one end face to a central portion thereof, and two second communication holes 30a and 30b are formed on an outer peripheral side of the first communication hole 29. A cylindrical holder 31 passes through the sleeve 23 and an end portion thereof fits the first communication hole 29 to be fixed, thereby forming a first oil passage 32 communicating from an inside the holder 31 to the first communication hole 29, and a second oil passage 33 communicating from a portion between the sleeve 23 and the holder 31 to the second communication holes 30a and 30b. Also, in the rotary valve 27, four coupling grooves 34a, 34b, 34c and 34d are formed on the outer peripheral surface thereof in a peripheral direction, and the first communication hole 29 communicates with the coupling grooves 34a and 34c by the coupling holes 35a and 35c, respectively, on the other hand, the second communication holes 30a and 30b communicate with the coupling grooves 34b and 34d by the coupling holes 35a and 35b, respectively.
In the rotary valve 27, a cylindrical second rotating member 36 rotatably fits the outer peripheral surface thereof. In the second rotating member 36, eight cylinders 37a to 37h are formed on an outer peripheral portion thereof at even intervals in the peripheral direction so as to open outward, and pistons 38a to 38h are movably supported on the cylinders 37a to 37h, respectively, in a radial direction of the rotary valve 27. Rollers 39a to 39h are mounted on tip ends of the pistons 38a to 38h, respectively, and the rollers 39a to 39h are rotatably supported around an axis parallel to an axial direction of the rotary valve 27. Also, compression coil springs 40a to 40h as pressing units are interposed in the cylinders 37a to 37h, respectively, and the compression coil springs 40a to 40h press the rollers 39a to 39h of the cylinders 37a to 37h, respectively, against the cam surface 26a, 26b, 26c and 26d of the cam 26 to contact, by biasing force thereof.
That is to say, each of the pistons 38a to 38h are arranged so as to be opposed to the cam 26 of the first rotating member 25 in the radial direction, and the rollers 39a to 39h contact the cam surfaces 26a, 26b, 26c and 26d of the cam 26 by the biasing force of the compression coil springs 40a to 40h. Sealed oil chambers 41a to 41h are formed between the pistons 38a to 38h and the cylinders 37a to 37h, respectively, and when the first and second rotating members 25 and 36 relatively rotate, each of the pistons 38a to 38h reciprocate by the cam surfaces 26a, 26b, 26c and 26d through the rollers 39a to 39h, so that the volumes of the oil chambers 41a to 41h are expanded or contracted. Also, the oil chambers 41a to 41h can communicate with the coupling grooves 34a to 34d through the coupling holes 42a to 42h.
In addition, a cylindrical coupling tube 43 is fixed to one plane surface portion of the second rotating member 36. On the other hand, a circular supporting plate 44 is rotatably supported on the partition wall 20a of the rear case 20 through the bearing 21c, and an end portion of a cylindrical output shaft 45 fits a through-hole 44a of the supporting plate 44 to be integrally joined by a joining member 46. An outer peripheral portion of a flange portion 44b integrally formed with the supporting plate 44 fits an inner peripheral portion of the coupling tube 43 by a spline 47, and the coupling tube 43 and the supporting plate 44, that is to say, the second rotating member 36 and the output shaft 45 are coupled so as to be integrally rotatable. Meanwhile, a bearing 48 is interposed between the other plane surface portion of the second rotating member 36 and the rotating plate 24, a bearing 49 is interposed between the coupling tube 43 and the supporting plate 44, and a bearing 16c is interposed between the input shaft 14 and the output shaft 45.
As shown in
The forward/reverse switching device 51 has a planetary gear mechanism, specifically, a single pinion planetary gear mechanism. That is to say, the planetary gear mechanism is composed of a sun gear 52, a ring gear 53 arranged concentrically with the sun gear 52, a plurality of pinion gears 54 meshing with the sun gear 52 and the ring gear 53, and a carrier 55 for rotatably and revolvably supporting the pinion gears 54. The sun gear 52 is drive-coupled to the primary shaft 15, and the ring gear 53 is drive-coupled to the output shaft 45. Also, a forward clutch 56 for controlling coupling and release of rotational elements composing the forward/reverse switching device 51 is provided, and a reverse brake 57 for controlling rotation and stop of the rotational elements is provided. The forward clutch 56 can control coupling and release of the sun gear 52 and the ring gear 53, and the reverse brake 57 can control rotation and stop of the carrier 55.
Meanwhile, a friction clutch, an electromagnetic clutch, a mesh clutch or the like can be applied as the above-described forward clutch 56, and a friction brake, an electromagnetic brake, a mesh brake or the like can be applied as the reverse brake 57. A hydraulic control actuator is used when applying the friction clutch, the mesh clutch, the friction brake, and the mesh brake, and an electromagnetic control actuator is used when applying the electromagnetic clutch and the electromagnetic brake. In this embodiment, the friction clutch (mesh clutch) and the friction brake (mesh brake) are controlled by using the hydraulic control actuator.
In addition, a third accommodating chamber A3 is formed inside the casing 17 in a space enclosed by the partition wall 18a of the front case 18 and the partition wall 19a of the center case 19. A stepless transmission 58 is provided in the third accommodating chamber A3. The stepless transmission 58 is for steplessly changing the rotational speed of the primary shaft 15 to transmit to a secondary shaft 59, and is arranged between the engine 11 and the forward/reverse switching device 51.
The stepless transmission 58 is a belt-type stepless transmission and has the above-described primary shaft 15 and secondary shaft 59, and the primary shaft 15 and the secondary shaft 59 are rotatably supported on the partition walls 18a and 19a so as to be parallel to each other. A primary pulley 60 is provided on the primary shaft 15 so as to be integrally rotatable, and a secondary pulley 61 is provided on the secondary shaft 59 so as to be integrally rotatable. An endless belt 62 is mounted on the primary pulley 60 and the secondary pulley 61.
The primary pulley 60 has a fixed sieve 60a integral with the primary shaft 15 and a movable sieve 60b movable in an axial direction of the primary shaft 15, and the endless belt 62 is mounted therebetween. A first hydraulic servomechanism 63 for moving the movable sieve 60b in the axial direction of the primary shaft 15 to allow the same to approach and leave the fixed sieve 60a is provided. On the other hand, the secondary pulley 61 has a fixed sieve 61a integral with the secondary shaft 59 and a movable sieve 61b movable in an axial direction of the secondary shaft 59, and the endless belt 62 is mounted on them. A second hydraulic servomechanism 64 for moving the movable sieve 61b in the axial direction of the secondary shaft 59 to allow the same to approach and leave the fixed sieve 61a is provided. A gear ratio can be steplessly changed by changing engaging positions of the primary pulley 60 and the secondary pulley 61 with respect to the belt 62 by the hydraulic servomechanisms 63 and 64, respectively.
Further, a gear transmission device 65 with which torque of the secondary shaft 59 is transmitted and a differential 66 are provided inside the casing 17, and a wheel 68 is coupled to the differential 66 through a drive shaft 67.
An electronic control unit (ECU) 71 for integrally controlling an entire vehicle is provided on the vehicle. That is to say, an ignition switch 72, an accelerator opening sensor 73, a brake stroke sensor 74, an engine rotational number sensor 75, a throttle opening sensor 76, a rotational number sensor 77 of the input shaft 14, a rotational number sensor 78 of the primary shaft 15, a rotational number sensor 79 of the secondary shaft 59, and a shift position sensor 80 are provided, and detection signals thereof are input to the ECU 71.
Also, a hydraulic control device 81 for controlling the above-described oil pump 22, forward/reverse switching device 51 and stepless transmission 58 is provided on the vehicle and can be controlled by the ECU 71. To the hydraulic control device 81, a first oil suction path (fluid suction path) 83, which is coupled to an oil retaining unit (fluid retaining unit, such as an oil pan) 82, is coupled, and a first oil exhaust path (fluid exhaust path) 85, which is coupled to an oil supplying unit (fluid supplying unit, such as the forward/reverse switching device 51 and a hydraulic control unit of the stepless transmission 58) 84, is coupled. Also, the hydraulic control device 81 is coupled to the oil pump 22 through the path switching device 86 and the control valve 87 for controlling the oil pump 22.
That is to say, as shown in
In the path switching device 86, a housing 91 has a hollow shape, and a first port 92 communicating with the first oil passage 32 as the first fluid path and a second port 93 communicating with the second oil passage 33 as the second fluid path are formed. Also, in the housing 91, a suction port 94 communicating with the second oil suction path 89 and two exhaust ports 95 and 96 communicating with the second oil exhaust path 90 are formed. In the housing 91, a spool 97 as the moving body is movably supported, and on the spool 97, a valve unit 97a enabling communication and blocking between the first port 92 and the suction and exhaust ports 94 and 95, and a valve unit 97b enabling the communication and the blocking between the second port 93 and the suction and exhaust ports 94 and 96 are formed. Further, in the housing 91, a first pressure port 99 communicating with a first branched path 98 branched from the first oil passage 32 as the first fluid path and a second pressure port 101 communicating with a second branched path 100 branched from the second oil passage 33 as the second fluid path are formed on each end portion in the axial direction. A valve unit 97c on which the oil pressure from the first branched path 98 acts and a valve unit 97d on which the oil pressure from the second branched path 100 acts are formed on the spool 97.
Therefore, the path switching device 86 can switch the inflow direction and the outflow direction of the fluid in the first and second fluid paths by the movement of the spool 97 according to the difference in pressure between the first fluid path (first oil passage 32) and the second fluid path (second oil passage 33). That is to say, when the oil pressure in the first oil passage 32 as the first fluid path is higher than that in the second oil passage 33 as the second fluid path, the oil pressure in the first oil passage 32 acts from the first pressure port 99 through the first branched path 98 on the valve unit 97c, so that the spool 97 moves to right in
On the other hand, when the oil pressure in the second oil passage 33 is higher than that in the first oil passage 32, the oil pressure in the second oil passage 33 acts from the second pressure port 101 through the second branched path 100 on the valve unit 97d, so that the spool 97 moves to left in
Also, the second oil exhaust path 90 branches into the first oil exhaust path 85 and the oil circulation path 88, and a part of the oil exhausted from the oil pump 22 flows through the first oil exhaust path 85 to the oil supplying unit 84 and the rest flows to the oil circulation path 88. The oil flowing to the oil circulation path 88 joins the oil flowing from the first oil suction path 83 and is returned to the second oil suction path 89. The control valve 87 is provided on the oil circulation path 88. The control valve 87 is a flow amount adjusting valve for adjusting the flow amount of the oil flowing through the oil circulation path 88 by adjusting opening thereof. An amount of oil to be supplied to the oil supplying unit 84 changes a little according to operating condition but substantially constant, so that the control valve 87 can adjust a discharge amount from the oil pump 22 by adjusting the flow amount of the oil flowing through the oil circulation path 88.
Herein, operation of the above-described oil pump 22 of this embodiment is described in detail.
In the oil pump 22 of this embodiment, as shown in
That is to say, in the oil pump 22, the first and second rotating members 25 and 36 rotate in a counterclockwise direction in
In this case, suction force acts from the oil chamber 41f to the second oil passage 33 due to the expansion of the oil chamber 41f, and on the other hand, compression force acts from the oil chamber 41h to the first oil passage 32 due to the contraction of the oil chamber 41h. Therefore, as described above, in the path switching device 86, the oil pressure in the first oil passage 32 becomes higher than that in the second oil passage 33 and the spool 97 moves to the first movement position. Then, the oil from the oil circulation path 88 flows to the second oil suction path 89 and the oil in the oil retaining unit 82 also flows through the first oil suction path 83 to the second oil suction path 89, flows through the suction port 94 and the second port 93 to the second oil passage 33, and is sucked into the oil chamber 41f. On the other hand, the oil in the oil chamber 41h flows from the first oil passage 32 through the first port 92 and the exhaust port 95 to the second oil exhaust path 90, and a part thereof is discharged through the first oil exhaust path 85 to the oil supplying unit 84 and the rest flows to the oil circulation path 88.
At that time, in a case in which the control valve 87 is fully opened, the flow amount of the oil flowing through the oil circulation path 88 is not limited and flow resistance is small, and the flow resistance of the oil discharged from the oil chamber 41h to the second oil exhaust path 90 is also small. Therefore, when the roller 39h of the piston 38h moves by rolling from the cam surface 26a to the cam surface 26b, the resistance when the piston 38h moves inward of the cylinder 37h is also small, so that the second rotating member 36 easily rotates in the direction opposite to that of the first rotating member 25 (in the clockwise direction in
Also, when the control valve 87 is fully closed, the flow amount of the oil flowing through the oil circulation path 88 becomes 0 and entire oil discharged from the oil pump 22 is supplied to the oil supplying unit 84, and consumption energy of the oil pump 22 is suppressed.
Meanwhile, although only the operation of the piston 38f, the roller 39f, and the oil chamber 41f, and the piston 38f, the cylinder 37f and the oil chamber 41h is described in the operational description of the above-described oil pump 22, all of the pistons 38a to 38h, cylinders 37a to 37h and oil chambers 41a to 41h operate similarly by the cam 26.
When the torque of the input shaft 14 is transmitted through the oil pump 22 to the output shaft 45, the torque of the output shaft 45 is transmitted through the forward/reverse switching device 51 to the stepless transmission 58 and is decelerated by a predetermined gear ratio set herein. The torque decelerated by the stepless transmission 58 is transmitted through the gear transmission device 65 to the differential 66 and is transmitted through the drive shaft 67 to the wheel 68.
On the other hand, when an engine brake acts on the vehicle, in the oil pump 22, although the first and second rotating members 25 and 36 rotate in the counterclockwise direction in
In this case, the suction force acts from the oil chamber 41f to the first oil passage 32 due to the expansion of the oil chamber 41f, on the other hand, the compression force acts from the oil chamber 41h to the second oil passage 33 due to the contraction of the oil chamber 41h. Therefore, as described above, in the path switching device 86, the oil pressure in the second oil passage 33 becomes higher than that in the first oil passage 32 and the spool 97 moves to the second movement position. Then, the oil from the oil circulation path 88 flows to the second oil suction path 89 and the oil in the oil retaining unit 82 flows from the first oil suction path 83 to the second oil suction path 89, flows through the suction port 94 and the first port 92 to the first oil passage 32, and is sucked into the oil chamber 41f. On the other hand, the oil from the oil chamber 41h flows from the second oil passage 33 through the second port 93 and the exhaust port 96 to the second oil exhaust path 90, and a part thereof is discharged through the first oil exhaust path 85 to the oil supplying unit 84 and the rest flows to the oil circulation path 88.
In this manner, in the hydraulic apparatus according to the first embodiment, the first and second rotating members 25 and 36 are provided so as to be relatively rotatable with the same central axis O, the cam 26 is provided on the first rotating member 25, the pistons 38a to 38h are arranged on the second rotating member 36 so as to be opposed to the cam 25, the pistons 38a to 38h are pressed against the cam 26 so as to contact by the compression coil springs 40a to 40h, respectively, the oil chambers 41a to 41h of which volumes are expanded and contracted according to the movements of the pistons 38a to 38h are provided on the second rotating member 36, the first fluid path (first oil passage 32) and the second fluid path (second oil passage 33) through which the oil flows into and out from the oil chambers 41a to 41h are provided, and the path switching device 86 for switching the inflow direction and the outflow direction of the oil in the first and second fluid paths according to the difference in pressure between the first and second fluid paths is provided.
Therefore, by discharging the oil to a predetermined oil passage (second oil exhaust path 90) regardless of the rotational directions of each of the rotating members 25 and 36 due to the switch of the inflow direction and the outflow direction of the oil according to the difference in pressure between the first and second fluid paths by the path switching device 86, the oil can be appropriately supplied to the forward/reverse switching device 51 and the hydraulic control unit of the stepless transmission 58 as the oil supplying unit 84, and burning of the clutch and occurrence of shock when engaging in the forward/reverse switching device 51, and belt breakage in the stepless transmission 58 can be prevented. Also, since a check valve is not used in the oil path, the pressure loss is suppressed, so that occurrence of cavitation when sucking the oil and the operational inadequacy (cum nose jumping phenomenon) of the pistons 38a to 38h are suppressed, and further the mechanical efficiency can be improved. Further, the simple structure can be obtained without requiring special control and actuator.
Also, in the first embodiment, the spool 97 as the moving body for switching the inflow direction and the outflow direction of the oil in the first and second fluid paths by moving according to the difference in pressure between the first fluid path (first oil passage 32) and the second fluid path (second oil passage 33) is provided as the path switching device 86, and the spool 97 is made movable to the first movement position for setting the first fluid path to the outflow direction of the oil and switching the second fluid path to the inflow direction of the oil, and to the second movement position for setting the first fluid path to the inflow direction of the oil and switching the second fluid path to the outflow direction of the oil.
Therefore, by moving the spool 97 to the first and second movement positions according to the difference in pressure between the first and second oil passages 32 and 33, the inflow direction of the oil and the outflow direction of the oil in the first and second oil passages 32 and 33 can be switched, so that the oil can be appropriately sucked and discharged with the simple structure.
Also, in the first embodiment, as the path switching device 86, the first port 92 communicating with the first oil passage 32 as the first fluid path and the second port 93 communicating with the second oil passage 33 as the second fluid path are provided and the suction port 94 communicating with the oil suction path 83 and the exhaust ports 95 and 96 communicating with the oil exhaust path 85 are provided in the housing 91, and the communication relationship between the first and second ports 92 and 93 and the suction port 94 and the exhaust ports 95 and 96 are made switchable by the spool 97, and the first pressure port 99 with which the pressure in the first oil passage 32 acts on the spool 97 and the second pressure port 101 with which the pressure in the second oil passage 33 acts on the spool are provided.
Therefore, by allowing the oil pressures in the first and second oil passages 32 and 33 to act on the spool 97 through the pressure ports 99 and 101, the spool 97 moves to the first or second movement position according to the difference in pressure therebetween, and the communication relationship between the first and second ports 92 and 93 and the suction port 94 and the exhaust ports 95 and 96 can be switched by the movement of the spool 97, so that the oil can be appropriately sucked and discharged.
Also, in the first embodiment, the path switching device 86 is coupled to the oil retaining unit 82 through the oil suction path 83 and is coupled to the oil supplying unit 84 through the oil exhaust path 85, and the control valve 87 for controlling the flow amount of the oil is provided on the oil exhaust path 85. Therefore, by adjusting the flow amount of the oil in the oil exhaust path 85 by the control valve 87, a torque transmission amount between the first and second rotating members 25 and 36 can be adjusted, so that the oil can be appropriately sucked and discharged, and the torque can be appropriately transmitted between the first and second rotating members 25 and 36.
Also, in the first embodiment, the input shaft 14 is coupled to the first rotating member 25, the output shaft 45 is coupled to the second rotating member 36, the pistons 38a to 38h reciprocate by the difference in rotational speeds between the first and second rotating members 25 and 36, and the pressures in the fluid chambers 41a to 41h change, thereby the oil is sucked and discharged through the first and second fluid paths. Therefore, an appropriate oil discharge amount can be ensured based on the difference in rotational speed between the first and second rotating members 25 and 36.
In the second embodiment, as shown in
Also, a cylindrical rotary valve 112 is joined to the rotating plate 24, and the end plate 28 of the input shaft 14 fits an outer peripheral surface of the rotary valve 112 to be integrally joined. On the rotary valve 112, four coupling grooves 113a, 113b, 113c and 113d are formed on the outer peripheral surface thereof in the peripheral direction, and the coupling holes 114a, 114b, 114c and 114d communicating with the coupling grooves 113a, 113b, 113c and 113d, respectively, are formed on the inner peripheral surface thereof.
The second rotating member 36 rotatably fits on the outer peripheral surface of the rotary valve 112. On the second rotating member 36, the eight cylinders 37a to 37h are formed on the outer peripheral portion thereof at regular intervals in the peripheral direction, and the pistons 38a to 38h are movably supported by the cylinders 37a to 37h, respectively. The rollers 39a to 39h are mounted on the tip ends of the pistons 38a to 38h, respectively. Also, the compression coil springs 40a to 40h are interposed in the cylinders 37a to 37h, respectively, and the rollers 39a to 39h of the cylinders 37a to 37h, respectively, are pressed against the cam surfaces 26a, 26b, 26c and 26d of the cam 26 by the biasing force of each of the compression coil springs 40a to 40h. The oil chambers 41a to 41h are formed between the pistons 38a to 38h and the cylinders 37a to 37h, respectively. The oil chambers 41a to 41h can communicate with the coupling grooves 113a, 113b, 113c and 113d through the coupling holes 42a to 42h.
Also, the coupling tube 43 is fixed to the second rotating member 36, and this fits the supporting plate 44 joined to the output shaft 45 by the spline 47, so that the coupling tube 43 and the supporting plate 44, that is to say, the second rotating member 36 and the output shaft 45 are coupled so as to be integrally rotatable.
In the oil pump 111 of this embodiment, the coupling holes 114a and 114c, the coupling grooves 113a and 113c, and the coupling holes 42a to 42h are provided as the first fluid path through which the oil as the fluid flows into or out from the fluid chambers 41a to 41h, and the coupling holes 114b and 114d, the coupling grooves 113b and 113d, and the coupling holes 42a to 42h are provided as the second fluid path. A rotating body 115 composing the path switching device concentrically rotatably fits an inner peripheral portion of the rotary valve 112. The rotating body 115 switches the inflow direction and the outflow direction of the fluid in the first and second fluid paths according to the difference in pressure between the first and second fluid paths. Also, the control valve 87 controls the flow amount of the oil in the oil circulation path 88.
In the rotating body 115, an exhaust chamber 116 is formed from one end face to a central portion thereof, and two suction chambers 117a and 117b are formed on an outer peripheral side of the exhaust chamber 116. A cylindrical holder 118 passes through the sleeve 23 and the end portion thereof fits the exhaust chamber 116 and is fixed, thereby forming an exhaust oil passage 119 communicating from an inside the holder 118 to the exhaust chamber 116 is formed and a suction oil passage 120 communicating from a portion between the sleeve 23 and the holder 118 to the suction chambers 117a and 117b. The exhaust chamber 116 communicates with the second oil exhaust path 90 through the exhaust oil passage 119, and can communicate with the coupling holes 114a and 114c as the first fluid path or the coupling holes 114b and 114d as the second fluid path through the coupling holes 121a, 121b, 121c and 121d. Also, the suction chambers 117a and 117b communicate with the second oil suction path 89 through the suction oil passage 120, and can communicate with the coupling holes 114a and 114c as the first fluid path or the coupling holes 114b and 114d as the second fluid path through the coupling holes 122a and 122b.
Also, first pressure chambers 123a and 123b with which the coupling holes 114a and 114c as the first fluid path communicate, respectively, are provided between the rotary valve 112 and the rotating body 115, and second pressure chambers 124a and 124b with which the coupling holes 114b and 114d as the second fluid path communicate, respectively, are provided between the rotary valve 112 and the rotating body 115. That is to say, two notch portions 115a and 115b are formed on the outer peripheral portion of the rotating body 115 at regular intervals in the peripheral direction, on the other hand, projecting portions 112a and 112b engaging with the notch portions 115a and 115b, respectively, are formed on the outer peripheral portion of the rotary valve 112. Therefore, although the rotating body 115 can rotate relative to the rotary valve 112, end faces of the notch portions 115a and 115b abut the projecting portions 112a and 112b of the rotary valve 112, respectively, so that a rotation area thereof is regulated. Then, the first pressure chambers 123a and 123b and the second pressure chambers 124a and 124b are divided by the notch portions 115a and 115b, respectively. The first pressure chambers 123a and 123b communicate with the coupling holes 114a and 114c through the coupling grooves 115c and 115d, respectively, and the second pressure chambers 124a and 124b communicate with the coupling holes 114b and 114d through the coupling grooves 115e and 115f, respectively.
Therefore, the inflow direction and the outflow direction of the fluid in the first and second fluid paths can be switched by the rotation of the rotating body 115 according to the difference in pressure between the first fluid path (coupling holes 114a and 114c) and the second fluid path (coupling holes 114b and 114d). That is to say, when the oil pressure in the coupling holes 114a and 114c as the first fluid path is higher than that in the coupling holes 114b and 114d as the second fluid path, the oil pressure in the coupling holes 114a and 114c acts on the first pressure chambers 123a and 123b through the communication grooves 115c and 115d, so that the rotating body 115 moves by rolling in the clockwise direction in
On the other hand, when the oil pressure in the coupling holes 114b and 114d as the second fluid path is higher than that in the coupling holes 114a and 114c as the first fluid path, as shown in
Also, the second oil exhaust path 90 branches into the first oil exhaust path 85 and the oil circulation path 88, and a part of the oil exhausted from the oil pump 22 flows through the first oil exhaust path 85 to the oil supplying unit 84 and the rest flows to the oil circulation path 88. The oil flowing to the oil circulation path 88 joins the oil flowing from the first oil suction path 83 and is returned to the second oil suction path 89. The control valve 87 is provided on the oil circulation path 88. The control valve 87 is the flow amount adjusting valve, and the discharge amount from the oil pump 111 can be adjusted by adjusting the flow amount of the oil flowing through the oil circulation path 88 by adjusting the opening thereof.
Herein, the operation of the above-described oil pump 111 of this embodiment is described in detail.
In the oil pump 111 of this embodiment, as shown in
In this case, the suction force acts from the oil chamber 41f to the coupling hole 114b due to the expansion of the oil chamber 41f, on the other hand, the compression force acts from the oil chamber 41h to the coupling hole 114a due to the contraction of the oil chamber 41h. Therefore, as described above, the oil pressure in the coupling hole 114a becomes higher than that in the coupling hole 114b and the oil pressure in the coupling hole 114a acts on the first pressure chamber 123a, and the rotating body 115 rotates in a clockwise direction in
At that time, when the control valve 87 is fully opened, the flow amount of the oil flowing through the oil circulation path 88 is not limited and the flow resistance is small, and the flow resistance of the oil discharged from the oil chamber 41h to the second oil exhaust path 90 is also small. Therefore, when the roller 39h of the piston 38h moves by rolling from the cam surface 26a to the cam surface 26b, the resistance when the piston 38h moves inward of the cylinder 37h is also small, and the second rotating member 36 easily rotates in the direction opposite to that of the first rotating member 25 (in the clockwise direction in
On the other hand, the first and second rotating members 25 and 36 rotate in the counterclockwise direction in
In this case, the suction force acts from the oil chamber 41f on the coupling hole 114c due to the expansion of the oil chamber 41f, on the other hand, the compression force acts from the oil chamber 41h on the coupling hole 114b due to the contraction of the oil chamber 41h. Therefore, as described above, the oil pressure in the coupling hole 114b becomes higher than that in the coupling hole 114c, so that the oil pressure in the coupling hole 114b acts on the second pressure chamber 124b and the rotating body 115 rotates in a counterclockwise direction in
In this manner, in the hydraulic apparatus of the second embodiment, the first and second rotating members 25 and 36 are provided so as to be relatively rotatable with the same central axis O, the cam 26 is provided on the first rotating member 25, the pistons 38a to 38h are arranged on the second rotating member 36 so as to be opposed to the cam 26, the pistons 38a to 38h are pressed against the cam 26 so as to contact by the compression coil springs 40a and 40h, respectively, the oil chambers 41a to 41h of which volumes are expanded and contracted according to the movements of the pistons 38a and 38h are provided on the second rotating member 36, the first fluid path (coupling holes 114a and 114c) and the second fluid path (coupling holes 114b and 114d) through which the oil flows into or out from the oil chambers 41a and 41h are provided, and the rotating body 115 for switching the inflow direction and the outflow direction of the oil in the first and second fluid paths according to the difference in pressure between the first and second fluid paths is provided.
Therefore, the inflow direction and the outflow direction of the oil is switched by the rotating body 115 according to the difference in pressure between the first and second fluid paths to supply the oil to the predetermined oil passage (the second oil exhaust path 90) regardless of the rotational directions of each of the rotating members 25 and 36, so that the oil can be appropriately supplied to the forward/reverse switching device 51 and the hydraulic control unit of the stepless transmission 58 as the oil supplying unit 84, thereby preventing the burning of the clutch in the forward/reverse switching device 51 and the occurrence of the shock when engaging, and the belt breakage in the stepless transmission 58. Also, since the check valve is not used in the oil path, the pressure loss is suppressed, and the occurrence of the cavitation when sucking the oil and the operational inadequacy (cam nose jumping phenomenon) of the pistons 38a to 38h are suppressed, and further, the mechanical efficiency can be improved.
Also, in the second embodiment, the rotating body 115 is concentrically rotatably supported inside the second rotating member 36, on the rotating body 115, the exhaust chamber 116 with which the second oil suction path 89 communicates and the first or second fluid path can communicate and the suction chambers 117a and 117b with which the second oil exhaust path 90 communicates and the first or second fluid path can communicate are provided, and the first pressure chambers 123a and 123b rotatable by the pressure in the first fluid path acting on the rotating body 115 and the second pressure chambers 124a and 124b rotatable by the pressure in the second fluid path acting on the rotating body 115 are provided, and the communication relationship between the first and second fluid paths and the suction chamber 116 and the exhaust chambers 117a and 117b can be switched according to the rotational position of the rotating body 115.
Therefore, space efficiency is improved and the smaller device can be obtained, and a large opening area of the oil passage can be ensured, so that it becomes possible to further suppress the pressure loss, and since the rotating body is rotatable relative to the second rotating member 36, the operational inadequacy can be prevented. The oil pressure acts on the rotating body 115 through the first pressure chambers 123a and 123b or the second pressure chambers 124a and 124b according to the difference in pressure between the coupling holes 114a and 114c and the coupling holes 114b and 114d, and the inflow direction of the oil and the outflow direction of the oil in the coupling holes 114a and 114c and the coupling holes 114b and 114d can be switched by the movement of the rotating body 115 to the first movement position and the second movement position, and the oil can be appropriately sucked and discharged with the simple structure.
The oil pump as the hydraulic apparatus of the third embodiment is composed such that the first and second rotating members 25 and 36 are supported so as to be relatively rotatable, the input shaft 14 is coupled to the first rotating member 25 through the rotary valve 27 and the cam 26 is provided on the first rotating member 25, the pistons 38a to 38h are movably supported on the second rotating member 36 and are pressed against the cam 26 by the compression coil springs 40a to 40h, respectively, and the output shaft 45 is coupled thereto, as shown in
The oil pump 22 is provided with a path switching device 131 for controlling the operation thereof, as shown in
In this embodiment, the spool 97 is movable to the first movement position for setting the first oil passage 32 to the outflow direction of the oil and switching the second oil passage 33 to the inflow direction of the oil, and to the second movement position for setting the first oil passage 32 to the inflow direction of the oil and switching the second oil passage 33 to the outflow direction of the oil according to the difference in pressure between the first and second oil passages 32 and 33, and is biasingly supported at the first movement position by gravity as biasing means. In this case, as shown in
Also, the second oil exhaust path 90 is branched into the first oil exhaust path 85 and the oil circulation path 88, and a part of the oil exhausted from the oil pump 22 flows through the first oil exhaust path 85 to the oil supplying unit 84 and the rest flows to the oil circulation path 88. The oil flowing to the oil circulation path 88 joins the oil flowing from the first oil suction path 83 and is returned to the second oil suction path 89. The control valve 87 is provided on the oil circulation path 88. The control valve 87 is the flow amount adjusting valve, and the discharge amount from the oil pump 22 can be adjusted by adjusting the flow amount of the oil flowing through the oil circulation path 88 by adjusting the opening thereof.
Therefore, in the path switching device 131, the spool 97 moves downward, that is to say, to the first movement position, in the housing 91 by the gravity thereof and stops, and at that time, the first port 92 communicates with the exhaust port 95 by the valve unit 97a, and the second port 93 communicates with the suction port 94 by the valve unit 97b. In such a state, when the oil pressure in the first oil passage 32 is higher than that in the second oil passage 33 as the second fluid path, the oil pressure in the first oil passage 32 acts from the first pressure port 99 through the first branched path 98 on the valve unit 97c, so that the spool 97 is held at the first movement position. Therefore, the oil pressure in the second oil suction path 89 flows through the suction port 94 and the second port 93 to the second oil passage 33, and the oil pressure in the first oil passage 32 flows through the first port 92 and the exhaust port 95 to the second oil exhaust path 90.
On the other hand, when the oil pressure in the second oil passage 33 becomes higher than that in the first oil passage 32, the oil pressure in the second oil passage 33 acts from the second pressure port 101 through the second branched path 100 on the valve unit 97d, so that the spool 97 rises against the gravity and moves to the second movement position to stop. Therefore, the first port 92 communicates with the exhaust port 94 by the valve unit 97a and the second port 93 communicates with the exhaust port 96 by the valve unit 97b, and the oil pressure in the second oil suction path 89 flows through the suction port 94 and the first port 92 to the first oil passage 32, and the oil pressure in the second oil passage 33 flows through the second port 93 and the exhaust port 96 to the second oil exhaust path 90.
In this manner, in the hydraulic apparatus of the third embodiment, the spool 97 for switching the inflow direction and the outflow direction of the oil by moving according to the difference in pressure between the first and second oil passages 32 and 33 is provided in the housing 91 as the path switching device 131 for controlling the operation of the oil pump, and the spool 97 is supported so as to be movable to the first movement position for setting the first oil passage 32 to the oil outflow direction and switching the second oil passage 33 to the oil inflow direction and to the second movement position for setting the first oil passage 32 to the oil inflow direction and switching the second oil passage 33 to the oil outflow direction, and is biasingly supported at the first movement position by the gravity as the biasing means.
Therefore, by biasingly supporting the spool 97 at the first movement position, backflow of the oil can be prevented when starting the oil pump, and it is possible to discharge the oil at an early stage to supply to the oil supplying unit 84, and by vertically arranging the housing 91 of the spool 97, it is possible to allow the gravity to act on the spool 97, to easily biasingly support the same at the first movement position, so that the simple structure can be obtained.
Also, in the third embodiment, the input shaft 14 is coupled to the first rotating member 25 of the oil pump 22, the output shaft 45 is coupled to the second rotating member 36, and when the rotational speed of the first rotating member 25 is higher than that of the second rotating member 36, the high-pressure oil passage is set as the first oil passage 32, and the low-pressure oil passage is set as the second oil passage 33.
Therefore, when starting the engine 11, the backflow of the oil in the oil pump can be prevented, and the oil can be supplied to the oil supplying unit 84 at the early stage by the oil pump.
The oil pump as the hydraulic apparatus of the fourth embodiment is provided with a path switching device 141 for controlling the operation thereof, as shown in
In this embodiment, the spool 97 is movable to the first movement position for setting the first oil passage 32 to the outflow direction of the oil and switching the second oil passage 33 to the inflow direction of the oil and to the second movement position for setting the first oil passage 32 to the inflow direction of the oil and switching the second oil passage 33 to the outflow direction of the oil according to the difference in pressure between the first and second oil passages 32 and 33, and is biasingly supported at the first movement position by the compression coil spring 142 as the biasing means. In this case, the compression coil spring 142 is interposed between the end face on the first pressure port 99 side of the housing 91 and the valve unit 97c of the spool 97.
Therefore, in the path switching device 141, the spool 97 moves to the first movement position by the biasing force of the compression coil spring 142 to stop, and at that time, the first port 92 communicates with the exhaust port 95 by the valve unit 97a and the second port 93 communicates with the suction port 94 by the valve unit 97b. In this state, when the oil pressure in the first oil passage 32 is higher than that in the second oil passage 33 as the second fluid path, the oil pressure in the first oil passage 32 acts from the first pressure port 99 through the first branched path 98 on the valve unit 97c, so that the spool 97 is held at the first movement position. Therefore, the oil pressure in the second oil suction path 89 flows through the suction port 94 and the second port 93 to the second oil passage 33, and the oil pressure in the first oil passage 32 flows through the first port 92 and the exhaust port 95 to the second oil exhaust path 90.
On the other hand, when the oil pressure in the second oil passage 33 becomes higher than that in the first oil passage 32, the oil pressure in the second oil passage 33 acts from the second pressure port 101 through the second branched path 100 on the valve unit 97d, so that the spool 97 moves against the biasing force of the compression coil spring 142 and stops at the second movement position. Therefore, the first port 92 communicates with the exhaust port 94 by the valve unit 97a and the second port 93 communicates with the exhaust port 96 by the valve unit 97b, and the oil pressure in the second oil suction path 89 flows through the suction port 94 and the first port 92 to the first oil passage 32, and the oil pressure in the second oil passage 33 flows through the second port 93 and the exhaust port 96 to the second oil exhaust path 90.
In this manner, in the hydraulic apparatus of the fourth embodiment, the spool 97 for switching the inflow direction and the outflow direction of the oil by moving according to the difference in pressure between the first and second oil passages 32 and 33 is provided in the housing 91 as the path switching device 141 for controlling the operation of the oil pump, and the spool 97 is supported so as to be movable to the first movement position for setting the first oil passage 32 to the oil outflow direction and switching the second oil passage 33 to the oil inflow direction and to the second movement position for setting the first oil passage 32 to the oil inflow direction and switching the second oil passage 33 to the oil outflow direction, and is biasingly supported at the first movement position by the biasing force of the compression coil spring 142.
Therefore, by biasingly supporting the spool 97 at the first movement position by the biasing force of the compression coil spring 142, the backflow of the oil can be prevented when starting the oil pump, and it is possible to discharge the oil at the early stage to supply to the oil supplying unit 84, and by interposing the compression coil spring 142 between the housing 91 and the spool 97, spring force is allowed to always act on the spool 97 to biasingly support the same at the first movement position, and operability of the spool 97 can be improved.
In the fifth embodiment, as shown in
Also, the rotating body 115 is rotatably supported inside the second rotating member 36, and on the rotating body 115, the exhaust chamber 116 with which the second oil suction path 89 communicates and the first or second fluid path can communicate and the suction chambers 117a and 117b with which the second oil exhaust path 90 communicates and the first or second fluid path can communicate are provided, and the first pressure chambers 123a and 123b capable of rotating by the pressure in the first fluid path acting on the rotating body 115 and the second pressure chambers 124a and 124b capable of rotating by the pressure in the second fluid path acting on the rotating body 115 are provided, and the communication relationship between the first and second fluid paths and the suction chamber 116 and the exhaust chambers 117a and 117b can be switched according to the rotational position of the rotating body 115.
In this case, the rotating body 115 is capable of switching to the inflow direction of the oil and the outflow direction of the oil by moving to the first movement position (position indicated in
In this embodiment, a brake 152 as restraining means is provided between the rear case 20 composing the casing 17 and the rotating plate 24 integral with the first rotating member 25. As the brake 152, the friction brake, the mesh brake and the electromagnetic brake can be applied, and when applying the friction brake and the mesh brake, the hydraulic control actuator is used, and when applying the electromagnetic brake, the electromagnetic control actuator is used, and the actuators can be controlled by the electronic control unit according to an operating state of the vehicle. Also, an oil pressure source 153 as fluid supplying means is coupled to the oil exhaust path 85 through an oil supplying path 154, and an electromagnetic on-off valve 155 is provided on the oil supplying path 154.
Also, the second oil exhaust path 90 branches into the first oil exhaust path 85 and the oil circulation path 88, and a part of the oil exhausted from the oil pump 22 flows through the first oil exhaust path 85 to the oil supplying unit 84, and the rest flows to the oil circulation path 88. The oil flowing to the oil circulation path 88 joins the oil flowing from the first oil suction path 83 and is returned to the second oil suction path 89. The control valve 87 is provided on the oil circulation path 88. The control valve 87 is the flow amount adjusting valve and the discharge amount from the oil pump 22 can be adjusted by adjusting the opening thereof.
Therefore, the engine is driven and the first and second rotating members 25 and 36 rotate in the same direction (in the counterclockwise direction in
In this case, the oil chambers 41b, 41c, 41f and 41g are expanded and the oil chambers 41h, 41a, 41d and 41e are contracted, so that the oil pressures in the coupling holes 114a and 114c become higher than the oil pressures in the coupling holes 114b and 114d, and the oil pressures in the coupling holes 114a and 114c act on the first pressure chambers 123a and 123b to move the rotating body 115 to the first position. Then, the oil from the oil circulation path 88 flows to the second oil suction path 89 and the oil in the oil retaining unit 82 also flows through the first oil suction path 83 to the second oil suction path 89, flows through the suction oil passage 120 to be sucked into the oil chambers 41b, 41c, 41f and 41g. On the other hand, the oil in the oil chambers 41h, 41a, 41d and 41e flows through the exhaust oil passage 119 to the second oil exhaust path 90, and a part thereof is discharged through the first oil exhaust path 85 to the fluid supplying unit 84 and the rest flows to the oil circulation path 88.
On the other hand, the first and second rotating members 25 and 36 rotate in the same direction (in the counterclockwise direction in
In this case, the oil chambers 41a, 41b, 41e and 41f are expanded and the oil chambers 41c, 41d, 41g and 41h are contracted, so that the oil pressures in the coupling holes 114b and 114d become higher than the oil pressures in the coupling holes 114a and 114c, and the oil pressures in the coupling holes 114b and 114c act on the second pressure chambers 124a and 124b to move the rotating body 115 to the second position. Then, the oil from the oil circulation path 88 flows to the second oil suction path 89 and also the oil in the oil retaining unit 82 flows through the first oil suction path 83 to the second oil suction path 89, and is sucked into the oil chambers 41a, 41b, 41e and 41h through the suction oil passage 120. On the other hand, the oil in the oil chambers 41c, 41d, 41g and 41h flows through the exhaust oil passage 119 to the second oil exhaust path 90, and a part thereof is discharged through the first oil exhaust path 85 to the fluid supplying unit 84 and the rest flows to the oil circulation path 88.
Also, when the engine stops, the oil pump 151 of this embodiment can be used as the motor. That is to say, by activating the brake 152, in a state in which the first rotating member 25 is restrained, the electromagnetic on-off valve 154 is opened and the control valve 87 is fully closed, and the oil pressure is discharged from the oil pressure source 153. Then, the oil pressure of the oil pressure source 153 is supplied from the oil supplying path 154 through the second oil exhaust path 90 to the oil supplying unit 84 and is supplied to the oil pump 151. At that time, since the rotating body 115 is biasingly supported at the first movement position by the biasing force of the compression coil spring, the oil chambers 41b, 41c, 41f and 41g communicate with the coupling holes 114b and 114d through the coupling holes 42b, 42c, 42f and 42g and the coupling grooves 113b and 113d, and the oil chambers 41h, 41a, 41d and 41e communicate with the coupling holes 114a and 114c through the coupling holes 42h, 42a, 42d and 42e and the coupling grooves 113a and 113c.
Therefore, the oil pressure of the oil pressure source 153 flows from the oil supplying path 154 and the second oil exhaust path 89 through the exhaust oil passage 119 and the exhaust chamber 116, and is supplied to the oil chambers 41a and 41e through the coupling holes 121a and 121b, the coupling holes 114a and 114c, the coupling grooves 113a and 113c and the coupling holes 42 and 42e. Then, the oil chambers 41a and 41e are expanded by the supply of the oil pressure, and the pistons 38a and 38e move outward, so that the second rotating member 25 rotates in the counterclockwise direction in
In this manner, in the hydraulic apparatus of the fifth embodiment, the first and second rotating members 25 and 36 are supported so as to be relatively rotatable, the cum 26 is provided on the first rotating member 25, the pistons 38a to 38h movable while contacting the cam 25 are supported on the second rotating member 36, the first and second fluid paths through which the oil flows into and out from the oil chambers 41a to 41h of which volumes are expanded and contracted according to the movements of the pistons 38a to 38h are provided, the rotating body 151 for switching the flow direction of the oil by rotating according to the difference in pressure between the first and second fluid paths is provided, the brake 152 for restraining the first rotating member 25 is provided, and the oil pressure source 153 for supplying the oil pressure to the first fluid path is provided.
Therefore, when the engine is stopping, by supplying from the oil pressure source 153 through the second oil exhaust path 90 to the oil chambers 41a to 41h to rotate the second rotating member 25 by moving the pistons 38a to 38h, the torque of the second rotating member 36 can be output to the output shaft 45, and the oil pump 151 is allowed to serve as the motor.
Also, by interposing the compression coil spring between the rotary valve 112 and the rotating body 115, the rotating body 115 is biased at the first movement position. Therefore, by biasingly supporting the rotating body 115 at the first movement position, when starting the oil pump 151 in a state in which the engine is stopping, the second rotating member 36 can be rotated in the positive rotation direction and the appropriate torque can be ensured.
Meanwhile, although the first and second rotating members 25 and 36 are supported so as to be relatively rotatable, the input shaft 14 is coupled to the first rotating member 25 through the rotary valves 27 and 112, and the output shaft 45 is coupled to the second rotating member 36 in the above-described embodiments, the output shaft 45 may be coupled to the first rotating member 25 through the rotary valves 27 and 112, and the input shaft 14 may be coupled to the second rotating member 36.
Also, although the gravity by the vertical arrangement of the spool 97 or the biasing force of the compression coil spring 152 are used as the biasing means in the above-described embodiments, another spring such as tensile spring or plate spring and rubber or resin may be used as the biasing means. In addition, the biasing means may be provided on the rotating body of the second embodiment.
Further, although the input shaft 14 is coupled to the first rotating member 25, the output shaft 45 is coupled to the second rotating member 36, and the first rotating member 25 can be restrained by the brake 152 in the above-described fifth embodiment, when the input shaft 14 is coupled to the second rotating member 36 and the output shaft 45 is coupled to the first rotating member 25, the second rotating member 36 may be restrained by the brake 152.
As described above, the hydraulic apparatus according to the present invention is for supplying the fluid to the predetermined oil passage regardless of the rotational direction of the rotating member, and further, for improving the mechanical efficiency and improving the versatility, and is preferably used in all kinds of hydraulic apparatuses.
Number | Date | Country | Kind |
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2007-188213 | Jul 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2008/063054 | 7/18/2008 | WO | 00 | 1/14/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/011429 | 1/22/2009 | WO | A |
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3785250 | Steiger | Jan 1974 | A |
4006668 | Steiger | Feb 1977 | A |
4889096 | Brunel | Dec 1989 | A |
5901802 | Sunohara et al. | May 1999 | A |
7048516 | Maier et al. | May 2006 | B2 |
20090060765 | Kuwabara et al. | Mar 2009 | A1 |
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2 108866 | Apr 1990 | JP |
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Number | Date | Country | |
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20100202902 A1 | Aug 2010 | US |