JP2011140994A - Lubricating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lubricating device capable of suppressing an increase of power loss in a power source when lubricating a lubrication object part while a vehicle drives at high speed. <P>SOLUTION: A lubricating device includes: a lubrication object part that requiring lubrication or cooling by oil; an oil reservoir that oil is reserved; a rotating member that is rotated by power of a power source and that scrapes the reserved oil up; an oil pump that is driven by power of the power source. The lubricating device also includes: a first lubrication means (step S3) that lubricates the lubrication object part by oil discharged from the oil pump by engaging clutches, while a vehicle relatively drives at low speed, in the lubricating device including the clutches connecting or blocking a power transmission path between the power source and the oil pump; and a second lubrication means (step S2) for stopping the oil pump by releasing the clutches while the vehicle relatively drives at high speed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a lubrication apparatus that can supply oil discharged from an oil pump to a lubrication target site.

  An example of a lubrication apparatus that can supply oil discharged from an oil pump to a lubrication target part is described in Patent Document 1. The lubrication apparatus described in Patent Document 1 is used for lubricating a four-wheel drive manual transmission. The manual transmission is provided in a power transmission path from the engine to the rear differential device, and the manual transmission is disposed inside the casing. An oil sump is formed at the bottom of the casing. The manual transmission has a drive shaft and a front drive shaft that transmit engine power and are arranged in parallel to each other. Further, the drive shaft and the front drive shaft are connected by a transmission gear train so that power can be transmitted. A part of this transmission gear train is immersed in the oil reservoir. A hollow driven shaft is attached to the front drive shaft so as to be relatively rotatable, and a pump drive gear is formed on the driven shaft.

  On the other hand, an oil pump is provided inside the casing, and a clutch drum is connected to a drive shaft of the oil pump via a clutch member. A pump gear is formed on the clutch drum, and the pump gear and the pump drive gear are meshed with each other. Further, an oil pump control unit for connecting / disconnecting the clutch member is provided, and oil temperature data and vehicle speed data are input to the oil pump control unit.

  In the manual transmission described in Patent Document 1, when the engine is started and the power is transmitted to the manual transmission, the oil in the oil pool is sprung up by the rotation of the gears of the transmission gear train, and each lubrication is performed. It is said that a necessary part is lubricated by oil splashes. Further, when the vehicle speed is zero (stopped) or at a low speed, or when the oil temperature is low, the energization to the clutch member is cut off and the clutch member is released. As a result, the oil pump is stopped, and the drive loss of the oil pump is eliminated when the engine is started, when idling, when traveling at a low vehicle speed, and when the oil viscosity is relatively high.

  In contrast, when the vehicle speed is equal to or higher than the set vehicle speed or the oil temperature is equal to or higher than the set oil temperature, the clutch member is energized and the clutch member is engaged. Then, the engine power is transmitted to the oil pump via the drive shaft and the driven shaft, and the oil pump is driven. As a result, the oil in the oil reservoir is sucked into the oil pump, and the oil discharged from the oil pump is supplied to each lubrication required portion.

  Patent Document 2 describes a vehicle that includes an oil pump driven by an engine and includes a clutch that connects or disconnects a power transmission path between the engine and the oil pump. Further, Patent Document 3 describes an example of a vehicle in which no hydraulic pressure is generated in the hydraulic circuit when the engine is stopped, and hydraulic pressure is generated in the hydraulic circuit when the engine is driven. Furthermore, Patent Documents 4 and 5 describe examples of a vehicle that is provided with an oil pump that generates hydraulic pressure that lubricates components constituting the drive device, and that can drive the oil pump with an engine. An example of a vehicle drive device having a hydraulic control circuit that controls a hydraulic friction engagement device of an automatic transmission for a vehicle and an electric oil pump that is a hydraulic source of the hydraulic control circuit is described in Patent Document 6. ing.

JP 2000-337485 A JP 2009-190474 A JP-A-8-135762 JP 2009-023427 A Japanese Patent Laid-Open No. 8-197962 JP 2007-253903 A

  In the lubricating device described in Patent Document 1 above, when the vehicle runs at a low speed, the clutch member is released and the oil pump is stopped. Is configured to be lubricated. However, when the vehicle travels at a low speed, the number of rotations of the transmission gear that jumps up the oil is low, so that there is a case where the oil cannot be sufficiently supplied to each lubrication required portion. In addition, when the speed of the transmission gear is relatively high and a relatively large amount of oil can be sprinkled by the rotation of the transmission gear, the clutch member is engaged to Therefore, there is a problem that the oil is excessively supplied to each lubrication required portion and the power loss of the engine increases.

  The present invention has been made in order to solve the above-described problems. Lubrication that can suppress an increase in power loss of a power source when lubricating a portion to be lubricated with oil when the vehicle is traveling at high speed. The object is to provide an apparatus.

  In order to achieve the above object, the invention according to claim 1 is directed to a lubrication target portion that requires lubrication or cooling with oil when power is transmitted from the power source of the vehicle to the drive wheels, and the lubrication target portion is lubricated. Or an oil reservoir in which oil to be cooled is stored, a rotating member immersed in the oil reservoir, and rotated by the power of the power source to scrape up the oil in the oil reservoir and supply it to the lubrication target site; Lubrication provided with an oil pump that is driven by the power of a power source and that discharges oil that lubricates the portion to be lubricated, and a clutch that connects and disconnects a power transmission path between the power source and the oil pump. In the apparatus, when the vehicle travels at a relatively low speed and the lubrication target portion is lubricated with oil scraped up by the rotation of the rotating member. The vehicle is relatively engaged with the first lubricating means for driving the oil pump by the power of the power source by engaging the clutch, and lubricating the lubrication target portion with the oil discharged from the oil pump. And a second lubricating means for releasing the clutch and stopping the oil pump when the portion to be lubricated is lubricated by the oil scraped up by the rotation of the rotating member. It is characterized by that.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect, an actuator is provided that applies an external force to the clutch to control the engagement and disengagement of the clutch. The lubricating device is configured to be released when the external force applied from the actuator is relatively lowered while being released when the force is increased.

  According to a third aspect of the present invention, in addition to the configuration of the first or second aspect, an input element to which the torque of the power source is transmitted, an output element connected to the drive wheel so as to be able to transmit power, and the input A reaction force element responsible for the reaction force of the torque input to the element, and an electric motor connected to the reaction force element, and controlling the number of revolutions of the electric motor to control the input element and the output element. A continuously variable transmission capable of continuously changing a gear ratio between the two is provided, and a vehicle body that supports the power source includes side members provided along a front-rear direction of the vehicle. The output shaft of the motor, the rotation shaft of the oil pump, and the clutch are disposed on the same rotation axis, and the rotation axis is disposed along the left-right direction of the vehicle. What is a clutch? The oil motor is disposed at different positions in the direction along the rotation axis, and the casing in which the electric motor, the oil pump, and the clutch are housed is provided, and the oil is disposed in a radial direction centered on the rotation axis. The outer peripheral end of the electric motor is arranged outside the outer peripheral end of the pump and the outer peripheral end of the clutch, and the oil pump or the outer side of the electric motor is disposed outside the electric motor in the direction along the rotation axis. At least a part of the clutch is disposed, the casing is formed with a first storage portion in which the electric motor is disposed, and the oil pump or the clutch is formed continuously with the first storage portion. And the second storage portion in which at least one of the two is disposed at a different position in the direction along the rotation axis. The circumscribed circle of the second storage section centered on the rotation axis is smaller than the circumscribed circle of the first storage section, and the second storage section in the height direction of the vehicle. The lubricating device is characterized in that the upper end of the side member is disposed below the lower end of the side member.

  According to the first aspect of the invention, when the vehicle is traveling at a relatively low speed, it is difficult to secure the required amount of oil in the lubrication target portion with the amount of oil scraped up by the rotation of the rotating member. By engaging and driving the oil pump with the power of the power source, the oil discharged from the oil pump can be supplied to the lubrication target site. On the other hand, when the vehicle is traveling at a relatively high speed, it is easy to secure the required amount of oil in the lubrication target portion by the amount of oil scraped up by the rotation of the rotating member. Stop the pump. Therefore, an increase in power loss of the power source can be suppressed when the vehicle is traveling at a relatively high speed.

  According to the invention of claim 2, in addition to obtaining the same effect as that of the invention of claim 1, the clutch is released when the external force applied from the actuator is relatively increased, while the external force applied from the actuator is relatively When the speed is lowered, the clutch is engaged. Therefore, even when a failure occurs in which the external force applied from the actuator is relatively reduced, the oil pump can be driven by the power of the power source.

  According to the invention of claim 3, in addition to obtaining the same effect as that of the invention of claim 1 or 2, by controlling the rotation speed of the electric motor, the input element and the output element of the continuously variable transmission are controlled. The gear ratio can be changed steplessly. In addition, the circumscribed circle of the second storage portion around the rotation axis is smaller than the circumscribed circle of the first storage portion, and the upper end of the second storage portion is lower than the lower end of the side member in the vehicle height direction. Therefore, the contact between the second storage portion and the side member can be avoided, and the mountability of the lubricating device in the vehicle is improved.

It is a flowchart which shows the example of control of the lubricating device in this invention. 1 is a schematic diagram illustrating an overall configuration of a vehicle including a lubricating device according to the present invention. FIG. 3 is a longitudinal sectional view of a transaxle of the vehicle shown in FIG. 2. It is a map used for control of the lubricating device in this invention. It is a schematic diagram which shows the other example of the lubricating device of this invention.

  A configuration example of a vehicle to which the present invention is applied will be described with reference to FIG. The vehicle 1 shown in FIG. 2 is a hybrid vehicle having an engine 2 and an electric motor MG2 as a driving power source. The engine 2 is a power unit that converts thermal energy generated when fuel is burned into kinetic energy and outputs the kinetic energy. As the engine 2, an internal combustion engine, specifically, a gasoline engine, a diesel engine, an LPG engine, or the like can be used. The engine 2 is supported by a part of the vehicle body and is disposed in the engine room. A crankshaft that is an output shaft of the engine 2 is configured to be rotatable about a rotation axis A <b> 1 disposed along the left-right direction of the vehicle 1. A power distribution device 5 is provided in a path from the crankshaft of the engine 2 to the drive wheels 4. The power distribution device 5 is housed in a hollow casing 6, and the casing 6 is attached to the outer wall of the engine 2. On the other hand, the vehicle body includes a side member 7 that extends along the front-rear direction of the vehicle 1. The vehicle body is reinforced by the side members 7. Further, the side members 7 are provided on the left and right sides of the vehicle 1, and the casing 6 is disposed below the side members 7.

  As the power distribution device 5, a single pinion type planetary gear mechanism is used in this embodiment. In other words, the planetary gear mechanism is a mechanism that transmits power by the meshing force between the gears. And a carrier 11 that supports the rotation and revolution. The sun gear 8, the ring gear 9, and the carrier 11 are configured to be differentially rotatable with respect to each other, and the power distribution device 5 is disposed around the rotation axis A1. A carrier 11 that is an input element of the power distribution device 5 is connected to the input shaft 12 so that power can be transmitted. The input shaft 12 is arranged coaxially with the crankshaft, and the input shaft 12 and the crankshaft are connected so that power can be transmitted.

  Further, an electric motor MG1 is provided coaxially with the rotation axis A1. A power distribution device 5 is disposed between the engine 2 and the electric motor MG1 in a direction along the rotation axis A1. The electric motor MG1 is a motor generator that has both a power running function that converts electrical energy into kinetic energy and a regenerative function that converts kinetic energy into electrical energy. The electric motor MG1 is provided in the casing 6. The electric motor MG1 has a stator 13 fixed to the casing 6 and a rotor 14 arranged inside the stator 13. The stator 13 and the rotor 14 are both coaxially arranged around the rotation axis A1. The inner side of the stator 13 means the inner side in the radial direction centered on the rotation axis A1. A hollow output shaft 14A is connected to the rotor 14 of the electric motor MG1, and the output shaft 14A is connected to the sun gear 10 that is a reaction force element of the power distribution device 5 so that power can be transmitted. The input shaft 12 is disposed in the output shaft 14A. The ring gear 9 of the power transmission device 5 functions as an output element. The ring gear 9 functions as an output element. The ring gear 9 receives the reaction force of the engine torque by the electric motor MG1 and controls the rotation speed of the electric motor MG1. The ratio with the rotation speed of the ring gear 9, that is, the gear ratio can be changed steplessly (continuously). That is, the power transmission device 5 has a function as a continuously variable transmission.

  Furthermore, a counter drive gear 15 is connected to the ring gear 9 which is an output element of the power distribution device 5 so that power can be transmitted. The counter drive gear 15 is disposed between the engine 2 and the power distribution device 5 in a direction along the rotation axis A1. A counter shaft 16 is provided in parallel with the input shaft 12, and a counter driven gear 17 and a drive pinion gear 18 are formed on the counter shaft 16. The counter driven gear 17 is meshed with the counter drive gear 15. Further, a ring gear 20 of a differential 19 is engaged with the drive pinion gear 18, and a drive shaft 21 is connected to the differential 19 so as to be able to transmit power, and the drive wheel 4 is coupled to the drive shaft 21. Yes. The number of teeth of the drive pinion gear 18 is configured to be smaller than the number of teeth of the ring gear 20, and when the torque of the drive pinion gear 18 is transmitted to the ring gear 20 and both gears rotate, the ring gear 20 is more than the rotation number of the drive pinion gear 18. The number of rotations is lower. That is, the drive pinion gear 18 and the ring gear 20 constitute a final reduction gear (final gear). Thus, the continuously variable transmission and the final reduction gear are accommodated in the casing 6 to form a transaxle. The differential 19 is housed inside the casing 6, and the arrangement position of the differential 19 and the arrangement position of the power transmission device 5 partially overlap in the direction along the rotation axis A <b> 1. Note that the rotation axis B <b> 1 of the ring gear 20 of the differential 19 is at a position lower than the rotation axis of the power transmission device 5.

  On the other hand, the electric motor MG2 is disposed inside the casing 6, and the electric motor MG2 is constituted by a motor generator similar to the electric motor MG1. Further, the two electric motors MG1, MG2 are arranged at the same position in the direction along the rotation axis A1. The electric motor MG2 includes a stator 23 and a rotor 24. A gear 26 is formed on an output shaft 25 of the rotor 24. The gear 26 is meshed with the counter driven gear 17. Furthermore, a power storage device 33 is provided that can exchange electric power with the electric motors MG1 and MG2. The power storage device 33 may be a battery or a capacitor. Furthermore, the electric circuit may be configured so that power can be directly exchanged between the electric motor MG1 and the electric motor MG2 without going through the power storage device 33.

  Next, the lubrication mechanism provided inside the casing 6 will be described. This lubrication mechanism is a mechanism for supplying oil to a lubrication target portion, for example, a meshing portion of gears arranged inside the casing 6, a bearing supporting a rotating element, and the electric motors MG1, MG2. When oil is supplied to the lubrication target site, it is lubricated or cooled by the oil. In this embodiment, a scraping type lubrication mechanism and an oil pump type lubrication mechanism are provided as the lubrication mechanism.

  First, a scraping type lubrication mechanism will be described with reference to FIG. FIG. 3 is a longitudinal sectional view showing the configuration of the transaxle. The scraping-up type lubrication mechanism has a ring gear 20 of a differential 19. As shown in FIG. 3, an oil reservoir 27 in which oil is stored is formed in the casing 6 (bottom portion). A part of the outer peripheral side of the ring gear 20 is immersed in the oil reservoir 27. For this reason, when the ring gear 21 rotates, oil is blown upward by centrifugal force, and the blown oil is supplied directly or indirectly to the lubrication target portion. As shown in FIG. 3, a ring gear 20 is disposed behind the power distribution device 5 in the front-rear direction of the vehicle 1. The rotation axis of the ring gear 20 is disposed below the rotation axis of the power distribution device 5 and the rotation axes of the electric motors MG1, MG2.

  Next, an oil pump type lubrication mechanism will be described. An oil pump 28 is provided inside the casing 6. The oil pump 28 has a rotating shaft 28A, and is configured to suck in oil and to discharge the sucked oil as the rotating shaft 28A rotates. Further, as the oil pump 28, any of a gear pump, a vane pump, a piston pump, and the like may be used. The rotation shaft 28A of the oil pump 28 is disposed coaxially with the input shaft 12, and the rotation shaft 28A and the input shaft 12 are connected to each other through a clutch C1 so that power can be transmitted.

  The clutch C1 is a device that connects the input shaft 12 and the rotary shaft 28A so that power can be transmitted, and interrupts power transmission between the input shaft 12 and the rotary shaft 28A. For example, a friction clutch can be used as the clutch C1. The friction clutch is configured to be movable in a direction along the rotation axis of the input shaft 12 and a disk-shaped plate provided on the input shaft 12, and is connected to the rotation shaft 28A so as to transmit power. A clutch disk, a spring that generates a force that presses the clutch disk in a direction along the rotation axis to bring the plate into contact with the clutch disk, and a force that moves the clutch disk in a direction opposite to the spring force. And an actuator 32 to be generated.

  As this actuator 32, a hydraulic actuator or an electromagnetic actuator can be used. When a hydraulic actuator is used as the actuator 32, a hydraulic chamber that generates a force applied to the clutch disk, and a movable member that operates by the hydraulic pressure of the hydraulic chamber and generates a force that separates the clutch disk and the plate are provided. Can be used. The clutch C1 may be engaged when the hydraulic pressure in the hydraulic chamber is relatively low, while the clutch C1 may be released when the hydraulic pressure in the hydraulic chamber is relatively high.

  On the other hand, an electromagnetic actuator operates by an electromagnetic coil that forms a magnetic attractive force when a voltage is applied, and a force that separates the clutch disk and the plate by operating by the magnetic attractive force formed by the electromagnetic coil. The thing provided with the movable member which arises can be used. And what is necessary is just to comprise so that the clutch C1 may be released when a voltage is applied to an electromagnetic coil, while the clutch C1 in which the voltage is not applied to an electromagnetic coil is engaged.

  Next, the size and shape of the electric motor MG1, the clutch C1, and the oil pump 28 in the radial direction around the rotation axis A1 will be described. First, in the radial direction centering on the rotation axis A1, the outermost end of the clutch C1 and the outermost end of the oil pump 28 are both inside the outer end of the stator 13 of the electric motor MG1. The sizes and shapes of the electric motor MG1, the clutch C1, and the oil pump 28 are configured so as to be arranged. That is, the diameter of the circumscribed circle of the clutch C1 is configured to be smaller than the diameter of the circumscribed circle of the stator 24 of the electric motor MG1 in a plane perpendicular to the rotation axis A1. More specifically, the diameter of the circumscribed circle of the clutch C1 is smaller than the diameter of the inscribed circle of the rotor 14 of the electric motor MG1 in a plane perpendicular to the rotation axis A1. Further, the diameter of the circumscribed circle of the oil pump 28 is configured to be smaller than the diameter of the circumscribed circle of the stator 13 of the electric motor MG1 in a plane perpendicular to the rotation axis A1. More specifically, the diameter of the circumscribed circle of the oil pump 28 is smaller than the diameter of the inscribed circle of the rotor 14 of the electric motor MG1 in a plane perpendicular to the rotation axis A1.

  Next, the arrangement positions of the electric motor MG1, the clutch C1, and the oil pump 28 in the direction along the rotation axis A1 will be described. A clutch C1 is disposed between the oil pump 28 and the power transmission device 5 in the direction along the rotational axis A1. More specifically, the clutch C1 is arranged in the arrangement range of the electric motor MG1 in the direction along the rotation axis A1. Further, the oil pump 28 is arranged outside the arrangement range of the electric motor MG1 in the direction along the rotation axis A1. Specifically, the clutch C <b> 1 is disposed between the oil pump 28 and the power distribution device 5 in the direction along the rotation axis A <b> 1.

  Further, the shape and structure of the casing 6 will be described. In the casing 6, a range in which the electric motor MG <b> 1 is stored in the direction along the rotation axis A <b> 1 is the motor storage unit 60. In the direction along the rotational axis A1, the arrangement range of the motor storage unit 60 and the arrangement range of the side members 7 do not overlap. Moreover, the upper end 6A in the height direction of the vehicle 1 in the motor storage portion 60 is disposed above the lower end 7A of the side member 7 as shown in FIG. In the plane perpendicular to the rotation axis A1, the motor housing 60 has a non-circular cross section. Further, the lower end 6 </ b> B of the casing 6 is disposed below the lower end 7 </ b> A of the side member 7. Further, a portion extending in a direction along a plane perpendicular to the rotation axis A1 is formed, for example, a rear cover 29, which is continuous with the motor housing 60, and the rear cover 29 has the rotation axis line. A protruding portion 30 protruding in the direction along A1 is formed continuously. The protrusion 30 has a cylindrical shape, and a part of the oil pump 28 is disposed in the protrusion 30 in the direction along the rotation axis A1. The upper end 30 </ b> A of the protrusion 30 in the height direction of the vehicle 1 is disposed below the lower end 7 </ b> A of the side member 7, and the protrusion 30 does not contact the side member 7.

  The control system of the vehicle 1 will be described. The vehicle is provided with an electronic control device 31. The electronic control device 31 includes the vehicle speed, the oil temperature of the oil in the casing 6, the accelerator opening, the engine speed, and the like. Sensor or switch signals are detected. The electronic control device 31 stores data for controlling engine output, data for controlling outputs of the electric motors MG1 and MG2, and data for controlling engagement and disengagement of the clutch C1. Based on a signal input to the electronic control device 31 and data stored in the electronic control device 31, engine output, outputs of the electric motors MG1 and MG2, and engagement and release of the clutch C1 are controlled.

  Next, control of the vehicle 1 will be described. First, when the stopped engine 2 is started when the vehicle 1 is stopped, the electric motor MG1 is driven as an electric motor, the torque is transmitted to the engine 2 for cranking, fuel injection and Ignition is performed and the engine 2 is rotated autonomously. Further, after the engine 2 autonomously rotates, the required driving force in the vehicle 1 is determined based on the vehicle speed and the accelerator opening, and the target output borne by the engine 2 and the electric motor MG2 are calculated based on the required driving force. The target output to be borne by is required. In controlling the rotational speed and torque of the engine 2 based on the target output, the target engine rotational speed and the target engine torque are obtained so that the fuel efficiency of the engine 2 is optimized. Then, the gear ratio of the power distribution device 5 is controlled so that the actual engine speed approaches the target engine speed. Specifically, the gear ratio of the power distribution device 5 is changed by controlling the rotation speed of the electric motor MG1. Further, the actual engine torque is controlled to be close to the target engine torque by controlling the opening degree of the electronic throttle valve of the engine 2. When the engine 2 is operated and torque is transmitted to the carrier 11, which is an input element of the power distribution device 5, the reaction force is received by the electric motor MG1, and the torque output from the ring gear 9 of the power distribution device 5 is It is transmitted to the drive wheel 4 via the counter drive gear 15, the counter shaft 16, the differential 19, and the drive shaft 21 to generate a driving force.

  On the other hand, when the electric motor MG2 is operated, the rotation speed and torque of the electric motor MG2 are controlled based on the target output of the electric motor MG2. The torque of the electric motor MG2 is transmitted to the drive wheels 4 via the counter driven gear 16. As described above, the vehicle 1 shown in FIG. 2 is a hybrid vehicle having the engine 2 and the electric motor MG2 as a power source that generates power to be transmitted to the drive wheels 4, and of the engine 2 or the electric motor MG2, at least Control for transmitting torque output from one side to the drive wheel 4 can be executed.

  Next, the operation and control for lubricating the lubrication target portion existing inside the casing 6 while the vehicle 1 is traveling will be described. When transmitting torque from the power source, particularly from the engine 2 to the drive wheel 4, heat generation, wear, seizure, etc. may occur in the meshing portion of the gear, the rotating shaft and the bearing supporting the gear. There is sex. Therefore, a portion to be lubricated, such as a meshing portion of the gears or a bearing supporting the rotating shaft and the gear, is cooled and lubricated with oil. Moreover, since the electric motors MG1 and MG2 also generate heat, they may be cooled by oil.

  First, “scrubbing lubrication” in which oil is scraped by a rotating element will be described. In this embodiment, since a part of the ring rear 20 is immersed in the oil reservoir 27 as shown in FIG. 3, when the ring gear 20 rotates counterclockwise, the oil in the oil reservoir 27 is scraped up by the ring gear 20, And it is blown away by centrifugal force. The oil thus blown off is supplied directly to the lubrication target site or indirectly, and the lubrication target site is lubricated or cooled by the oil. Here, supplying the oil directly to the lubrication target site means that the oil blown into the air adheres to the lubrication target site. For example, since the power distribution device 5 and the ring gear 20 are disposed at the same position in the direction along the rotation axis A <b> 1, the oil blown off by the ring gear 20 adheres directly to the power distribution device 5. On the other hand, when oil is indirectly supplied to the lubrication target part, the oil blown into the air once adheres to the inner surface of the casing 6 or a catch tank (not shown) provided inside the casing 6. 2), and then supplied to the lubrication target site via the wall surface of the casing 6 or the oil passage. In addition, the lubrication object site | part to which oil is supplied via a catch tank or an oil path is arrange | positioned in the position different from the ring gear 20 in the direction along rotation axis A1. Furthermore, the oil that has lubricated or cooled the lubrication target part returns to the oil reservoir 27 by its own weight.

  Next, lubrication using the oil pump 28 will be described. When the clutch C1 is engaged, the oil pump 28 is driven by engine torque. Then, the oil in the oil reservoir 27 is sucked into the oil pump 28, and the oil discharged from the oil pump 28 is supplied to the lubrication target portion. On the other hand, when the clutch C1 is released, the engine torque is not transmitted to the oil pump 28, and the oil pump 28 stops. In this embodiment, when the portion to be lubricated is lubricated or cooled with oil, the oil pump 28 is driven or stopped based on conditions such as oil temperature or vehicle speed, that is, the clutch C1 is engaged. Or release control. Hereinafter, an example of control for engaging and releasing the clutch C1 will be described.

(First control example)
This first control example controls the engagement and disengagement of the clutch C1 based on the oil temperature, and this first control example uses the map of FIG. FIG. 4 shows the relationship between the oil temperature and the power loss (oil pump loss) due to the drive of the oil pump 28. As shown in the map of FIG. 4, the power loss due to the driving of the oil pump 28 tends to become relatively large as the oil temperature decreases, and the startability of the engine 2 decreases. This is because the viscosity of the oil becomes relatively high as the oil temperature decreases. In addition, when the temperature is low, the output of the power storage device 33 that supplies electric power to the electric motor MG <b> 1 decreases, which causes the startability of the engine 2 to decrease.

  Therefore, in the first control example, when the engine 2 is started by the electric motor MG1, when the oil temperature detected by the oil temperature sensor is equal to or lower than the predetermined oil temperature th1, control is performed to release the clutch C1. To do. On the other hand, when the oil temperature detected by the oil temperature sensor exceeds a predetermined oil temperature th1, control is performed to engage the clutch C1. As described above, when the engine 2 is started by the electric motor MG1, the clutch C1 is released when the oil temperature detected by the oil temperature sensor is equal to or lower than the predetermined oil temperature th1. Power loss at the start can be reduced. Further, if the clutch C1 is released, the power of the engine 2 is not consumed for driving the oil pump 28, so that the fuel efficiency of the engine 2 can be improved. Further, since the clutch C1 is released when the engine 2 is started at a low temperature when the output of the power storage device 33 is lowered, the output of the power storage device 33 necessary for starting the engine 2 can be reduced. Therefore, it leads to cost reduction of the whole system mounted on the vehicle 1.

(Second control example)
This second control example controls the engagement and disengagement of the clutch C1 based on the vehicle speed, and a specific example thereof will be described based on the flowchart of FIG. First, it is determined whether or not the vehicle 1 is traveling at a high vehicle speed (step S1). The criterion for determining whether or not the vehicle speed is high in step S <b> 1 is a value determined by the relationship between the amount of oil necessary for lubricating the portion to be lubricated and the amount of oil scraped up by the rotation of the ring gear 20. For example, if the number of rotations of the ring rear 20 is equal to or higher than a predetermined number of rotations, the amount of oil necessary for lubricating the lubrication target portion can be secured by the amount of oil scraped up by the rotation of the ring gear 20. On the other hand, if the rotational speed of the ring rear 20 is less than the predetermined rotational speed, the amount of oil that is required to lubricate the lubrication target portion cannot be secured by the amount of oil that is scraped up by the rotation of the ring gear 20. It should be noted that the amount of oil necessary to lubricate the portion to be lubricated when the vehicle 1 is traveling and the number of rotations of the ring gear 20 to ensure the necessary amount of oil are experimentally determined. Further, since the rotation speed of the ring gear 20 increases as the vehicle speed increases, the reference vehicle speed to be used for the determination in step S1 is obtained in advance based on the relationship between the vehicle speed and the rotation speed of the ring gear 20, The reference vehicle speed is stored in the electronic control unit 31.

  Then, when the determination in step S1 is affirmative, the ring gear 20 is rotating at a relatively high rotational speed, and the oil to be lubricated by the rotation of the ring gear 20 is used to lubricate the portion to be lubricated. This means that the necessary amount of oil can be secured. Therefore, if the determination in step S1 is affirmative, control to release the clutch C1 is performed (step S2), and this control routine is terminated. When the control in step S2 is performed, it is possible to avoid the power of the engine 2 being consumed for driving the oil pump 28, and the fuel efficiency of the engine 2 can be improved.

  On the other hand, a negative determination in step S1 means that the amount of oil scraped up by the rotation of the ring gear 20 cannot secure the amount of oil necessary to lubricate the portion to be lubricated. Therefore, if a negative determination is made in step S1, control for engaging the clutch C1 is performed (step S3), and this control routine is terminated. When the control in step S3 is performed, the oil pump 28 is driven by the engine torque, and the oil discharged from the oil pump 28 is supplied to the lubrication target portion. Therefore, it is possible to avoid an insufficient amount of oil for lubricating the portion to be lubricated. As described above, when the control of FIG. 1 is executed, regardless of whether or not the vehicle 1 travels at a high vehicle speed, the necessary amount of oil in the lubrication target part can be supplied to the lubrication target part. It is possible to achieve both the effect of reducing power loss when the vehicle 1 travels at a high vehicle speed.

  Furthermore, in this embodiment, the clutch C <b> 1 is configured to be engaged when an external force is not applied from the actuator 32, while being released when an external force is applied from the actuator 32. Therefore, when the process proceeds to step S3 in the flowchart of FIG. 1 and the clutch C1 is engaged, it is possible to suppress slack due to the engagement delay of the clutch C1. In particular, when a hydraulic actuator is used as the actuator 32, it can be avoided that the engagement speed of the clutch C1 is relatively slow due to a delay in the rise of the hydraulic pressure in the hydraulic chamber. Even when the actuator 32 fails and external force cannot be applied from the actuator 32 to the clutch C1, the oil pump 28 is driven by the power of the engine 2 and the oil discharged from the oil pump 28 is used as a lubrication target site. Can be supplied. Therefore, the required amount of oil in the lubrication target part can be ensured while the vehicle 1 is traveling. In the lubrication apparatus shown in FIG. 2, either the first control example or the second control example can be selected and executed, or the first control example and the second control example can be switched. The first control example and the second control example are not performed at the same time.

  On the other hand, in this embodiment, the outer diameters of the oil pump 28 and the clutch C1 are configured to be smaller than the outer diameter of the electric motor MG1. An oil pump 28 and a clutch C1 are disposed at a position farther from the engine 2 than the electric motor MG1. And the upper end 30A of the protrusion part 30 in which a part of the oil pump 28 is disposed is disposed below the lower end 7A of the side member 7. Therefore, it is possible to avoid contact (interference) between a part of the casing 6 and the side member 7 and to improve the mountability of the transaxle with respect to the vehicle 1.

  Next, another configuration example of the lubricating device will be described with reference to FIG. In the configuration shown in FIG. 5, the same components as those shown in FIG. 2 are denoted by the same reference numerals as those in FIG. When the lubricating device shown in FIG. 2 is compared with the lubricating device shown in FIG. 5, the arrangement positions of the clutch C1 and the oil pump 28 are different in the direction along the rotation axis A1. More specifically, in the lubrication apparatus shown in FIG. 5, the oil pump 28 is disposed between the clutch C1 and the electric motor MG1 in the direction along the rotation axis A1. Further, the rotary shaft 28A of the oil pump 28 is configured to be hollow, and the input shaft 12 is disposed in the rotary shaft 28A. The arrangement range of the oil pump 28 and the arrangement range of the electric motor MG1 partially overlap in the direction along the rotation axis A1. Further, the arrangement range of the clutch C1 and the arrangement range of the electric motor MG1 do not overlap in the direction along the rotation axis A1. Further, a rear cover 29 is formed continuously at the end of the motor housing 60 in the direction along the rotation axis A1, and the rear cover 29 is formed in a conical shape (tapered shape). Specifically, it has a shape that protrudes toward the outside of the casing 6 in a direction along the rotation axis A1. That is, the rear cover 29 is inclined in the direction of reducing the diameter as the distance from the electric motor MG1 increases. The arrangement range of the rear cover 29 and the arrangement range of the side members 7 do not overlap in the direction along the rotation axis A1, and the rear cover 29 is located below the side members 7 in the height direction of the vehicle 1. Has been placed.

  In the vehicle 1 and the lubricating device shown in FIG. 5, the same operational effects as those in FIG. 2 can be obtained with respect to the same components as the vehicle 1 and the lubricating device shown in FIG. In the lubrication apparatus shown in FIG. 5, either the first control example or the second control example can be selected and executed, and the first control example and the second control example can be switched. Can be executed. In the lubrication apparatus shown in FIG. 5, both the first control example and the second control example are not executed at the same time. Furthermore, in the embodiment of FIG. 5, the rear cover 29 is disposed below the side member 7. Therefore, contact (interference) between the rear cover 29 and the side member 7 can be avoided, and the mountability of the transaxle to the vehicle 1 is improved.

  Here, the correspondence between the functional means shown in the flowchart of FIG. 1 and the configuration of the present invention will be described. Step S3 corresponds to the first lubricating means of the present invention, and step S2 corresponds to the present invention. This corresponds to the second lubricating means. 2 and FIG. 3 and the configuration of the present invention will be described. The vehicle 1 corresponds to the vehicle of the present invention, the ring gear 20 corresponds to the rotating member of the present invention, and the power The gears constituting the distribution device 5, the meshing parts of the other gears, various bearings, the electric motors MG1, MG2, and the like correspond to the lubrication target portions of the present invention, and the clutch C1 corresponds to the clutch of the present invention. The engine 2 corresponds to the power source of the present invention, the oil pump 28 corresponds to the oil pump of the present invention, the oil reservoir 27 corresponds to the oil reservoir of the present invention, and the drive wheel 4 corresponds to the drive of the present invention. It corresponds to a wheel, the actuator 32 corresponds to the actuator of the present invention, and the side member 7 corresponds to the side member of the present invention. Further, the carrier 11 corresponds to the input element of the present invention, the ring gear 9 corresponds to the output element of the present invention, the sun gear 8 corresponds to the reaction force element of the present invention, and the electric motor MG1 corresponds to the present invention. The output shaft 14A corresponds to the output shaft of the present invention, the power distribution device 5 corresponds to the continuously variable transmission of the present invention, and the rotation axis A1 corresponds to the rotation axis of the present invention. The casing 6 corresponds to the casing of the present invention, the motor storage portion 60 corresponds to the first storage portion of the present invention, and the cylindrical portion 30 shown in FIG. 2 and the rear cover 29 shown in FIG. This corresponds to the second storage portion of the present invention.

  In this invention, the shape of the 1st accommodating part and the 2nd accommodating part centering on a rotating shaft line may be circular in the plane perpendicular | vertical to a rotating shaft line, and does not need to be circular. That is, it is sufficient that the circumscribed circle of the second storage unit is smaller than the circumscribed circle of the first storage unit. 2 and 5, one of the oil pump and the clutch is disposed in the second storage portion, but both the oil pump and the clutch may be disposed in the second storage portion. Good. In the vehicles shown in FIGS. 2 and 5, a single pinion type planetary gear mechanism is shown as a power distribution device, but a double pinion type planetary gear mechanism may be used. Further, the power distribution device may use a planetary roller mechanism instead of the planetary gear mechanism. In other words, the power distribution device may be a continuously variable transmission configured such that the input element, the reaction force, and the output element can rotate relative to each other.

  Furthermore, the lubricating device of the present invention can also be applied to a vehicle using another power source, for example, a flywheel or a hydraulic motor, instead of the electric motor MG2. Further, the invention of claim 1 and the invention of claim 2 can be applied to a vehicle having a configuration in which the output shaft of the power source is arranged to be rotatable about a rotation axis along the longitudinal direction of the vehicle. . Further, the invention of claim 1 and claim 2 may be any vehicle provided with at least one of an engine, an electric motor or a flywheel as a power source. That is, for the invention of claim 1 or claim 2, the type of power source may be either singular or plural. Furthermore, the invention of claim 1 and the invention of claim 2 can be applied to a vehicle having a configuration in which the output shaft of the power source is arranged so as to be rotatable about a rotation axis along the longitudinal direction of the vehicle. is there. In the present invention, the rotating member that scoops up oil includes a pulley, a connecting drum that connects the rotating members, a sprocket, and the like in addition to the gear. Further, the clutch in the present invention includes a meshing clutch in addition to the friction clutch. That is, the clutch may be configured to be able to transmit and shut off power.

  DESCRIPTION OF SYMBOLS 1 ... Vehicle, 2 ... Engine, 4 ... Drive wheel, 5 ... Power distribution device, 6 ... Casing, 7 ... Side member, 8 ... Sun gear, 9 ... Ring gear, 11 ... Carrier, 14A ... Output shaft, 20 ... Ring gear, 27 DESCRIPTION OF SYMBOLS Oil reservoir, 28 ... Oil pump, 29 ... Rear cover, 30 ... Cylindrical part, 32 ... Actuator, 60 ... Motor storage part, A1 ... Rotary axis, C1 ... Clutch, MG1 ... Electric motor

Claims (3)

When power is transmitted from the power source of the vehicle to the driving wheels, a lubrication target portion that requires lubrication or cooling with oil, an oil sump in which oil that lubricates or cools the lubrication target portion, and the oil sump are stored. A rotating member that is immersed in the power source and rotated by the power of the power source to scoop up the oil in the oil reservoir and supply it to the lubrication target site, and is driven by the power of the power source, and the lubrication target site is In a lubricating device including an oil pump that discharges oil to be lubricated, and a clutch that connects and disconnects a power transmission path between the power source and the oil pump,
When the vehicle travels at a relatively low speed and the portion to be lubricated is lubricated by the oil scraped up by the rotation of the rotating member, the power of the power source is increased by engaging the clutch. The oil pump is driven by the first lubrication means for lubricating the portion to be lubricated by the oil discharged from the oil pump, and the vehicle travels at a relatively high speed and is scraped by the rotation of the rotating member. And a second lubricating means for releasing the clutch and stopping the oil pump when the portion to be lubricated is lubricated by the raised oil.   An actuator is provided that applies external force to the clutch to control its engagement and disengagement, and the clutch is released when the external force applied from the actuator is relatively increased, while the external force applied from the actuator The lubricating device according to claim 1, wherein the lubricating device is configured to be engaged when the pressure drops relatively.   An input element to which torque of the power source is transmitted, an output element connected to the drive wheel so as to be able to transmit power, a reaction force element responsible for a reaction force of the torque input to the input element, and the reaction force element And a continuously variable transmission capable of continuously changing the speed ratio between the input element and the output element by controlling the rotational speed of the electric motor. The vehicle body that supports the power source includes a side member provided along the front-rear direction of the vehicle, and the output shaft of the electric motor, the rotation shaft of the oil pump, and the clutch are the same rotation shaft. And the rotational axis is disposed along the left-right direction of the vehicle, and the oil pump and the clutch are disposed at different positions in the direction along the rotational axis. A casing in which the electric motor, the oil pump, and the clutch are housed is provided, and the outer periphery of the electric motor is positioned more radially than the outer peripheral end of the oil pump and the outer peripheral end of the clutch in the radial direction about the rotation axis. The end is arranged outside, and in the direction along the rotation axis, at least a part of the oil pump or the clutch is arranged outside the arrangement range of the electric motor, and the casing includes A first storage part in which the electric motor is disposed, and a second storage part that is formed continuously with the first storage part and in which at least one of the oil pump or the clutch is disposed are the rotation axis. Are arranged at different positions in the direction along the axis, and are centered on the rotation axis than the circumscribed circle of the first storage portion centered on the rotation axis. The circumscribed circle of the second storage portion is configured to be smaller, and the upper end of the second storage portion is disposed below the lower end of the side member in the height direction of the vehicle. The lubricating device according to claim 1 or 2.

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