JP4258904B2 - Control device for vehicle oil pump - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control device for a vehicle oil pump capable of supplying oil to a required oil portion of a vehicle transmission device by driving the oil pump with an electric motor.
[0002]
[Prior art]
Generally, a gear transmission, a winding transmission, and the like are used for a vehicle transmission. And it is comprised so that operation | movement of the component of these transmission devices may be controlled based on a predetermined condition. When the transmission device as described above is used in a transmission, specifically, a transmission that can automatically control the transmission gear ratio, the operation of the components of the transmission device can be controlled by hydraulic pressure, An example of such a hydraulic control device is described in Japanese Patent Laid-Open No. 7-174218.
[0003]
The hydraulic control device described in this publication has an electric motor, an electromagnetic clutch provided between the motor shaft of the electric motor and the transmission shaft, and an output shaft provided in parallel to the transmission shaft. ing. The transmission shaft is provided with a primary pulley, and the output shaft is provided with a secondary pulley. A belt is wound around the primary pulley and the secondary pulley.
[0004]
On the other hand, a shift hydraulic pump (oil pump) is provided at the end of the transmission shaft opposite to the position where the electric motor is disposed. The through shaft of this speed change hydraulic pump is directly connected to the motor shaft. When the speed change hydraulic pump is driven by the electric motor, the hydraulic pressure is supplied to the hydraulic chamber of the primary pulley to control the gear ratio, and the line pressure is supplied to the hydraulic chamber of the secondary pulley, which is necessary for torque transmission. Tension is applied to the belt. In addition, even when the vehicle is in a stopped state, a delay in the rise of the shifting hydraulic pressure at the time of starting is avoided by driving the electric motor and driving the shifting hydraulic pump under certain conditions where the starting of the vehicle is predicted. It is supposed to be possible.
[0005]
[Problems to be solved by the invention]
By the way, in a gear transmission and a winding transmission applied to a vehicle transmission, various power transmission elements such as gears or belts and pulleys move relative to each other when the vehicle travels. At the same time, these power transmission elements or bearing components that support the shaft may also move relative to each other, and the various power transmission elements and bearings may generate heat and wear, reducing their durability. . Therefore, it is necessary to forcibly supply oil (lubricating oil) to the heat generating part and to cool and lubricate various elements, and even when supplying such oil, an electric motor as described in the above publication is required. A system using an oil pump driven by a motor may be employed.
[0006]
On the other hand, when the vehicle is towed, the power input from the wheels is transmitted to the transmission, so that the various rotating elements and the relative components of the bearings are relative to each other in the same manner as when the vehicle is running. Movement occurs. For this reason, even when the vehicle is towed, it is necessary to supply lubricating oil to the oil-necessary part of the transmission. However, the hydraulic control device described in the above publication is for avoiding a delay in the rise of the shift hydraulic pressure when the vehicle starts, and does not take into consideration any hydraulic control when the vehicle is towed. However, the above problems could not be solved.
[0007]
The present invention has been made against the background of the above circumstances, and provides a control device for a vehicular oil pump capable of supplying oil to a required oil portion of a transmission when the vehicle is towed. It is aimed.
[0008]
[Means for Solving the Problem and Action]
In order to achieve the above object, the invention of claim 1 is based on an electric motor. The first oil pump is driving In a control device for a vehicle oil pump that is driven to supply oil to a transmission ,car When both are pulled, the electric motor The first oil pump is driven intermittently Oil pump driving hand that supplies oil by moving Step It is characterized by having.
[0009]
According to the invention of claim 1, when the vehicle is towed, the electric motor The first oil pump runs intermittently The oil is supplied to the oil required portion of the transmission. Therefore, the lubricity of the transmission device is improved.
[0010]
According to the invention of claim 1, the first option The electric power supplied to the electric motor for driving the oil pump is suppressed.
[0011]
Claim Item 2 According to the invention, in addition to the configuration of claim 1, the oil pump driving means is provided with a front side based on the oil requirement of the transmission. 1st o It includes a function of driving the oil pump. Claim Item 2 According to the invention, the same operation as that of the invention of claim 1 occurs, and oil is supplied according to the oil requirement of the transmission, so that unnecessary driving of the electric motor is avoided.
[0012]
Claim Item 3 In addition to the invention of claim 1, the present invention provides the oil pump drive means based on the travel distance of the towed vehicle. 1st o It includes a function of driving the oil pump. Claim Item 3 According to the invention, the same operation as that of the invention of claim 1 occurs, the necessary state of the oil is determined based on the travel distance of the towed vehicle, and the oil is supplied according to the determination result. Therefore, useless driving of the electric motor is avoided.
[0013]
Claim Item 4 According to the present invention, in addition to the structure of claim 1, the oil pump driving means is provided with 1st o It includes a function of driving the oil pump. Claim Item 4 According to the invention, the same operation as that of the invention of claim 1 occurs, and the necessary state of oil is determined based on the time during which the vehicle is pulled, and the oil is supplied according to the determination result. Therefore, useless driving of the electric motor is avoided.
[0014]
Claim Item 5 According to the present invention, in addition to the structure of claim 1, the oil pump driving means includes a front side based on a time during which the vehicle is towed and a vehicle speed of the towed vehicle. 1st o It includes a function of driving the oil pump. Claim Item 5 According to the invention, the same action as that of the invention of claim 1 occurs, and the necessary state of oil is determined based on the time when the vehicle is towed and the vehicle speed of the towed vehicle, and the oil is Supplied. Therefore, useless driving of the electric motor is avoided.
[0015]
Claim Item 6 According to the present invention, in addition to the structure of claim 1, the oil pump drive means includes a front 1st o It includes a function of driving the oil pump for a predetermined time. Claim Issue 6 According to the present invention, the same operation as that of the invention of claim 1 occurs, and since the oil supply time is controlled, unnecessary driving of the electric motor is avoided.
[0016]
Claim Item 7 According to the present invention, in addition to the structure of claim 1, the oil pump driving means includes a front end based on the temperature of the oil. 1st o It includes a function of controlling the drive of the oil pump. Claim Item 7 According to the invention, the same action as that of the invention of claim 1 occurs, and the supply of oil is controlled according to the viscosity of the oil. Therefore, it is possible to ensure an oil supply state in accordance with the oil supply response.
[0017]
Claim The invention of claim 8 is the invention of claims 1 to 7. In addition to any of the configurations, a start / stop control device for controlling start / stop of the driving force source of the vehicle is provided. A second oil pump is provided separately from the first oil pump as a hydraulic pressure source for supplying oil to the transmission, and the second oil pump can be driven by the power of the driving force source, The oil pump drive means is configured to operate the electric motor when the start / stop control device is in a state of stopping the drive force source and the vehicle is being pulled. The first o Drive the pump And turn on the transmission It includes a function for supplying a file.
[0018]
Claim According to the invention of claim 8, the claims 1 to 7 of In addition to the same effect as any of the above, the driving force source is stopped and the power of this driving force source 2nd o Even when the vehicle pump cannot be driven, , Drive the first oil pump Oil is supplied to the oil required part of the moving device.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described based on a specific example shown in the drawings. FIG. 2 shows a power plant for a hybrid vehicle to which the control device for a vehicle oil pump according to the present invention is applied. An internal combustion engine 1 as a power source for a vehicle is a device that outputs power by burning fuel, and can employ a gasoline engine, a diesel engine, an LPG engine, or the like. A turbine type engine may be used in addition to the type. In the following description, the internal combustion engine 1 is referred to as the engine 1.
[0020]
The engine 1 is configured to be able to electrically control the opening degree, fuel injection amount, ignition timing, etc. of the electronic throttle valve 1A, and is provided with a starter 1B for starting the engine 1. An electronic control unit (E / G-ECU) 8 for controlling the engine 1 is provided. The electronic control unit 8 is constituted by a microcomputer mainly including an arithmetic processing unit (CPU or MPU), a storage unit (RAM and ROM), and an input / output interface. Various electronic control devices are described below, but the configuration is almost the same. Then, in this electronic control unit 8, calculation is performed according to a program stored in advance based on input data such as accelerator opening, vehicle speed, shift signal, engine water temperature, etc., and a control signal is output based on the calculation result. It is configured.
[0021]
Furthermore, an electric motor (MG) 2 having a function as another power source is connected to the output side of the internal combustion engine 1. Furthermore, an automatic transmission 3 is disposed on the output side of the electric motor 2. The automatic transmission 3 includes a torque converter (T / C) 3, a transmission mechanism 5, and a hydraulic control unit 7 that controls the torque converter 3 and the transmission mechanism 5.
[0022]
In short, the electric motor 2 is a device that outputs torque by being supplied with electric power, and can employ a DC motor or an AC motor, and further, a so-called motor having a power generation function such as a fixed permanent magnet type synchronous motor. -A generator can be used. In the following description, the electric motor 2 is referred to as a motor / generator 2. In addition, a resolver 2 </ b> A for detecting the rotation speed and rotation angle of the motor / generator 2 is provided. Further, a battery 10 is connected to the motor / generator 2 via an inverter 9.
[0023]
An electronic control unit (MG-ECU) 11 is provided as a controller that controls the motor / generator 2. Calculation based on data input to the electronic control unit 11, current and frequency supplied to the motor / generator 2, electric power for charging the battery 10 using the motor / generator 2 as a generator, motor / generator 2 Is configured to control a regenerative braking torque or the like when functioning as a generator.
[0024]
FIG. 3 is a skeleton diagram showing the power plant of the hybrid vehicle shown in FIG. The engine 1 is provided with a crankshaft 1 </ b> C, and a power transmission shaft 121 is connected to the front cover 120 of the torque converter 4. The crankshaft 1C and the power transmission shaft 121 are connected so that power can be transmitted. Further, a rotor (not shown) of the motor / generator 2 is attached to the power transmission shaft 121, and a resolver 2A for detecting the rotation speed and rotation angle of the motor / generator 2 is provided.
[0025]
The torque converter 4 is configured so that its operation is controlled by hydraulic pressure, and a pump impeller 47 integrally coupled to the front cover 120 and a turbine runner 61 attached to an input shaft 57 of the transmission mechanism 5. And a stator 56 that changes the direction of oil flow inside the casing that forms part of the torque converter 4, and a lock-up clutch 62 that switches the power transmission state between the front cover 120 and the input shaft 57. is doing.
[0026]
When the lock-up clutch 62 is released, the power transmission state by the fluid is entered, and when the lock-up clutch 62 is engaged, the mechanical power transmission state is entered. When the lockup clutch 62 is released, the torque transmitted from the pump impeller 47 to the turbine runner 61 can be amplified by the function of the stator 56.
[0027]
Further, a mechanical oil pump 6 is disposed between the torque converter 4 and the transmission mechanism 5. The rotating shaft of the mechanical oil pump 6 is connected to the pump impeller 47. Therefore, the mechanical oil pump 6 can be driven by the power of the engine 1 or the motor / generator 2. The mechanical oil pump 6 has a function of generating an original pressure of hydraulic pressure acting on a friction engagement device (described later) such as a clutch or a brake on the transmission mechanism 5 side.
[0028]
On the other hand, the automatic transmission 3 shown in FIG. 3 is configured such that five forward speeds and one reverse speed can be set. That is, the automatic transmission 3 shown here includes a subtransmission unit 81 and a main transmission unit 82 following the torque converter 4 and the mechanical oil pump 6. The sub-transmission unit 81 is a so-called overdrive unit and is constituted by a set of single pinion type planetary gear mechanisms 83, a carrier 84 is connected to the input shaft 57, and between the carrier 84 and the sun gear 85. A one-way clutch F0 and an integrated clutch C0 are arranged in parallel. The one-way clutch F0 is engaged when the sun gear 85 rotates forward relative to the carrier 84 (rotation in the rotation direction of the input shaft 57). A multi-plate brake B0 for selectively stopping the rotation of the sun gear 85 is provided. A ring gear 86 that is an output element of the auxiliary transmission unit 81 is connected to an intermediate shaft 87 that is an input element of the main transmission unit 82.
[0029]
Accordingly, the sub-transmission unit 81 rotates as a whole with the planetary gear mechanism 83 in a state where the integrated clutch C0 or the one-way clutch F0 is engaged, so that the intermediate shaft 87 rotates at the same speed as the input shaft 57. It becomes a low speed stage. In the state where the brake B0 is engaged and the rotation of the sun gear 85 is stopped, the ring gear 86 is increased in speed with respect to the input shaft 57, and is rotated in the forward direction, so that the high speed stage is achieved.
[0030]
On the other hand, the main transmission unit 82 includes three sets of planetary gear mechanisms 88, 89, and 90, and their rotating elements are connected as follows. That is, the sun gear 91 of the first planetary gear mechanism 88 and the sun gear 92 of the second planetary gear mechanism 89 are integrally connected to each other, and the ring gear 93 of the first planetary gear mechanism 88 and the carrier 94 of the second planetary gear mechanism 89 Three members of the third planetary gear mechanism 90 and the carrier 95 are connected, and the output shaft 96 is connected to the carrier 95. The output shaft 96 is connected to the wheel 96A via a power transmission device (not shown). Further, the ring gear 97 of the second planetary gear mechanism 89 is connected to the sun gear 98 of the third planetary gear mechanism 90.
[0031]
In the gear train of the main transmission unit 82, the reverse gear and the four forward gears can be set, and clutches and brakes for that are provided as follows. First, the clutch will be described. The first clutch C1 is provided between the ring gear 97 of the second planetary gear mechanism 89 and the sun gear 98 of the third planetary gear mechanism 90 and the intermediate shaft 87 which are connected to each other. A second clutch C2 is provided between the sun gear 91 of the first planetary gear mechanism 88 and the sun gear 92 of the second planetary gear mechanism 89 and the intermediate shaft 87.
[0032]
Next, the brake will be described. The first brake B1 is a band brake and is arranged to stop the rotation of the sun gears 91 and 89 of the first planetary gear mechanism 88 and the second planetary gear mechanism 89. A first one-way clutch F1 and a second brake B2 that is a multi-plate brake are arranged in series between the sun gears 91 and 89 (that is, a common sun gear shaft) and the transmission housing 20, and The one-way clutch F1 is engaged when the sun gears 91 and 89 try to rotate in the reverse direction (rotation in the direction opposite to the rotation direction of the input shaft 57). A third brake B 3, which is a multi-plate brake, is provided between the carrier 99 of the first planetary gear mechanism 88 and the transmission housing 20.
[0033]
As a brake for stopping the rotation of the ring gear 100 of the third planetary gear mechanism 90, a fourth brake B4, which is a multi-plate brake, and a second one-way clutch F2 are arranged in parallel between the transmission housing 20. The second one-way clutch F2 is engaged when the ring gear 100 is about to reversely rotate. Among the rotating members of the transmission units 81 and 82 described above, a turbine rotation number sensor 101 that detects the rotation number of the clutch C0 of the sub-transmission unit 81 and an output shaft rotation number sensor 102 that detects the rotation number of the output shaft 96 are provided. Is provided. A so-called wet hydraulic multi-plate clutch is used for various clutches and brakes constituting a part of the transmission mechanism 5. In addition, an oil temperature sensor 3 </ b> A that detects the temperature of oil as hydraulic oil for the automatic transmission 3 is provided.
[0034]
In the automatic transmission 3 described above, frictional engagement devices such as clutches and brakes are engaged and disengaged as shown in FIG. 4 so that the first to fifth forward speeds and the reverse one speed are achieved. Can be set. That is, the automatic transmission 3 is a so-called stepped automatic transmission whose speed ratio can be changed stepwise (discontinuously). In FIG. 4, ◯ means that the friction engagement device is engaged, a blank means that the friction engagement device is released, and ◎ means that the friction engagement device is engaged during engine braking. The symbol Δ means that the friction engagement device is engaged but not related to power transmission.
[0035]
On the other hand, as shown in FIG. 2, a shift lever 127 for setting the control range of the gear ratio of the automatic transmission 3 is provided. The shift lever 127 and the hydraulic control unit 7 are mechanically connected. FIG. 5 shows the shift position selected by operating the shift lever 127. That is, the P (parking) position, R (reverse) position, N (neutral) position, D (drive) position, 4 positions, 3 positions, 2 positions, and L positions can be selected.
[0036]
When the non-driving position, for example, the P position or the N position is selected by operating the shift lever 127, the automatic transmission 3 cannot transmit power (torque) between the input shaft 57 and the output shaft 96. It becomes a state. Further, when one of the drive positions, for example, R position, D position, 4 position, 3 position, 2 position, and L position is selected, the automatic transmission 3 is connected to the input shaft 57 and the output shaft 96. The power can be transmitted between the two.
[0037]
Here, the D position is a position for setting any one of the forward first speed to the fifth speed by the automatic transmission 3 based on the traveling state of the vehicle such as the vehicle speed and the accelerator opening, and the four positions are Any of the first to fourth speeds, 3 positions are either the first speed to the 3rd speed, 2 positions are the 1st speed or 2nd speed, and the L position is the position for setting the 1st speed. It is. The 3rd position to the L position are positions for setting the engine brake range, and are configured so that the engine brake is applied at the highest speed among the speeds that can be set in each position. The shift position selected by operating the shift lever 127 is detected by the shift position sensor 127A.
[0038]
In this embodiment, the gear ratio of the automatic transmission 3 can be controlled by an automatic transmission control state in which the automatic transmission control state can be automatically controlled based on a signal input to the electronic control device 12, and by manual operation. The possible manual shift control state can be switched mutually. FIG. 6 shows a sports mode switch 76, which is disposed, for example, near an instrument panel (not shown) or a console box (not shown). When the sport mode switch 76 is turned on, the manual shift control state is set, and when the sport mode switch 76 is turned off, the manual shift control state is released.
[0039]
Meanwhile, the hybrid vehicle shown in FIG. 2 is provided with an electric oil pump 110 different from the mechanical oil pump 6. In addition, an electric motor 110A for driving the electric oil pump 110 is provided, and a battery 110B is connected to the electric motor 110A via an inverter 110C. An electronic control unit (ECU) 110D is provided as a controller that controls inverter 110C and battery 110B. The electronic control unit 110D is configured to perform calculation based on input data and control the motor 110A. By controlling the rotational speed of the electric motor 110A, the discharge amount of the electric oil pump 110 is increased or decreased. The electric oil pump 110 is driven when the engine 1 is stopped or the like, and has the same function as that of the mechanical oil pump 6.
[0040]
That is, the mechanical oil pump 6 and the electric oil pump 110 are both hydraulic pressure sources for the automatic transmission 3, and the hydraulic circuit for this is configured as shown in FIG. That is, a check ball mechanism 140 having two input ports 137 and 138 and one output port 139 is provided. The discharge port of the mechanical oil pump 6 communicates with one input port 137, and the discharge port of the electric oil pump 110 communicates with the other input port 138. Further, the hydraulic control unit 7 is provided with a primary regulator valve 141 for adjusting the line pressure to a pressure corresponding to the throttle opening or the accelerator opening, and the output port 139 of the check ball mechanism 140 is connected to the primary regulator valve 141. Is communicated.
[0041]
The check ball mechanism 140 is capable of moving the ball 142 that seals the input ports 137 and 138 by being pressed inside the input ports 137 and 138 into the space surrounded by the ports 137, 138, and 139. It is the valve mechanism arranged in. Therefore, when the discharge pressure of any one of the pumps 6 and 110 is high, the ball 142 is pressed inside the input port to which the pump having a low discharge pressure is connected. As a result, the hydraulic pressure is supplied to the primary regulator valve 141 from the pump having a high discharge pressure via the output port 139.
[0042]
On the other hand, as shown in FIG. 2, a motor / generator (MG) 128 is connected to a crankshaft 1 </ b> C of the engine 1 via a drive device 127. The motor / generator 128 has a function of transmitting power to the engine 1, a function of driving an auxiliary machine (not shown) such as an air conditioner compressor, and a function of a generator driven by the power of the engine 1. is doing.
[0043]
The drive device 127 includes a planetary gear mechanism (not shown), a friction engagement device (not shown) that switches a torque transmission state by the planetary gear mechanism, a one-way clutch (not shown), and the like. (Not shown). The drive device 127 includes a clutch mechanism (not shown) that connects and disconnects the power transmission path between the engine 1 and the motor / generator 128. The motor / generator 128 is electrically connected to a battery 130 via an inverter 129, and is provided with an electronic control unit (MG-ECU) 131 that controls the inverter 129 and the battery 130.
[0044]
The devices such as the engine 1, the motor / generators 2, 128, the automatic transmission 3, and the electric motor 110A are controlled based on various data indicating the state of the vehicle. For example, as shown in FIG. 8, various signals are input to an integrated control unit (ECU) 104 mainly composed of a microcomputer, and a calculation result based on the input signals is output as a control signal. Examples of input signals to the integrated control device 104 include signals from an ABS (anti-lock brake) computer, signals from a vehicle stabilization control (VSC: trademark) computer, engine speed NE, engine water temperature, and ignition switch IG. , SOC (State of Charge) of the batteries 10, 130, and 110B, a headlight on / off signal, and the like.
[0045]
Other input signals to the overall control device 104 include a defogger on / off signal, an air conditioner on / off signal, a vehicle speed signal, a hydraulic oil temperature of the automatic transmission 3, a signal of the shift position sensor 127A, and a side brake signal. On / off signal, foot brake on / off signal, catalyst (exhaust gas purification catalyst) temperature, accelerator opening, signal from cam angle sensor, sports shift signal, signal from vehicle acceleration sensor, driving force source brake force switch , A signal from the turbine rotational speed NT sensor, a signal from the resolver 2A, and the like.
[0046]
The ignition switch IG detects an operation state of an ignition key that controls start / stop of the engine 1 and start (specifically, standby state) / stop of the motor / generator 2. With this ignition switch IG, it is possible to detect each operation state of off (or lock), accessory, on and start. The hydraulic oil of the automatic transmission 3 is called automatic transmission fluid, and is used for engagement / release of a friction engagement device and lubrication and cooling of a heat generating portion.
[0047]
Examples of signals output from the general control device 104 include an ignition signal, an injection (fuel injection) signal, a signal to the starter 1B, and electronic control devices 11 and 131 which are controllers of the motor generators 2 and 128. To the speed reducer of the driving device 127, a signal to the AT solenoid, a signal to the AT line pressure control solenoid, a signal to the ABS actuator, a signal to the automatic stop control execution indicator, to the automatic stop control non-execution indicator , A signal to the sports mode indicator, a signal to the VSC actuator, a signal to the AT lockup control valve, and a control signal for the electric motor 110A for driving and stopping the electric oil pump 110.
[0048]
Here, the automatic stop control is a control for automatically stopping the engine 1 when a predetermined condition is satisfied when the vehicle is stopped, and is a control for reducing fuel consumption and exhaust gas. The electric oil pump 110 is basically controlled so as to supplement the hydraulic pressure by the mechanical oil pump 6 driven by the engine 1 or to output the hydraulic pressure in place of the mechanical oil pump 6. Even if the mechanical oil pump 6 does not output hydraulic pressure, the hydraulic pressure is not output depending on the traveling state of the vehicle. This is to improve fuel efficiency by preventing unnecessary consumption of the driving force as much as possible. In this embodiment, the electric oil pump 110 can be driven by the electric motor 110A even when the hybrid vehicle of FIG. 2 is towed.
[0049]
Here, the correspondence between the configuration of the present invention and the configuration of the embodiment will be described. That is, the engine 1 corresponds to the driving force source of the present invention, the electric motor 110A corresponds to the electric motor of the present invention, and the electric oil pump 110 corresponds to the present invention. The mechanical oil pump 6 corresponds to the second oil pump of the present invention, The automatic transmission 3 corresponds to the transmission device of the present invention, and the ignition key and the ignition switch IG correspond to the start / stop control device of the present invention.
[0050]
Next, a control example of the hybrid vehicle having the above configuration will be described based on the flowchart of FIG. First, input signals are processed by the various electronic control devices 8, 11, 12, 13, 110D, 131 and the general control device 104 (step S1). Based on the state of the vehicle, control for driving and stopping the engine 1 and the motor / generator 2 is performed.
[0051]
For example, the drive region of the engine 1 and the drive region of the motor / generator 2 are set based on the map shown in FIG. In this map, the drive region of the engine 1 and the drive region of the motor / generator 2 are set using the accelerator opening and the vehicle speed as parameters. The first to third speeds of the automatic transmission 3 are set in the drive region of the motor / generator 2, and the first to fifth speeds of the automatic transmission 3 are set in the drive region of the engine 1. .
[0052]
Following step S1, it is determined whether or not the ignition switch IG is turned on (step S2). If the determination in step S2 is affirmative, both the engine 1 and the motor / generator 2 are stopped. Further, it is determined whether or not the hybrid vehicle is being pulled (step S3). Whether or not the vehicle is being pulled can be determined from the vehicle speed.
[0053]
If the determination in step S3 is affirmative, the power (kinetic energy) of the wheel 96A is input to the automatic transmission 3, so that the rotating element constituting a part of the automatic transmission 3 rotates. As a result, the various gears or the components of the bearing holding the output shaft 96 move relative to each other, and these portions may generate heat and wear, resulting in a decrease in durability. However, since the engine 1 and the motor / generator 2 are stopped, the mechanical oil pump 6 cannot supply oil to the required oil part. Therefore, by performing the following control, oil is supplied to the oil required part and the part is cooled.
[0054]
First, the travel distance of the towed vehicle, specifically, the cumulative travel distance L is obtained (step S4). This cumulative travel distance L is
L = Σ
It is calculated by. Here, Σ is a value obtained by multiplying the vehicle speed and the vehicle traction time. Next, the average vehicle speed Va when the vehicle is being pulled is calculated (step S5). Average vehicle speed Va is
Va = (1 / time) × Σ
It is calculated by.
[0055]
Further, a time when the vehicle is pulled, specifically, an accumulated time T is obtained (step S6). This cumulative time T is
T = Σ
It is calculated by. Based on the cumulative travel distance L, the average vehicle speed Va, and the cumulative time T, a reference value (that is, an intermittent operation reference value) for intermittently operating the electric oil pump 110 while the vehicle is being towed is obtained. Calculation is performed (step S7). The intermittent operation reference value of the electric oil pump 110 is used to determine a time period after the electric oil pump 110 is once driven and then stopped and then driven again.
[0056]
The said intermittent operation time can be calculated | required from the map of FIG. 10, for example. FIG. 10 is a two-dimensional map of the average vehicle speed Va and the accumulated time T, and the average vehicle speed Va and the accumulated time T are grouped into a plurality of sets. And intermittent operation time is set corresponding to each group. The intermittent operation time may be the same for each group or may be different. That is, the intermittent operation time can be set shorter as the average vehicle speed Va increases. FIG. 11 is a diagram showing the relationship between the accumulated time T and the average vehicle speed Va.
[0057]
Further, when the intermittent operation reference of the electric oil pump 110 is obtained, only the cumulative travel distance L may be used as a reference. For example, every time the cumulative travel distance L reaches 10 km, the intermittent operation time may be set. Furthermore, the intermittent operation time of the electric oil pump 110 can be set according to the operating oil temperature of the automatic transmission 3. Specifically, the intermittent operation time of the electric oil pump 110 is set shorter as the hydraulic oil temperature becomes lower. The reason is that the lower the temperature is, the higher the viscosity of the hydraulic oil increases its flow resistance and lowers the lubricity at the oil required site.
[0058]
Thereafter, it is determined whether or not the intermittent operation time set in step S7 has elapsed (step S8). If the determination in step S8 is affirmative, the electric oil pump 110 is driven for a predetermined time (step S9). As a result, the oil is forcibly supplied to the oil required portion in the automatic transmission 3, and the portion is lubricated and cooled. Here, the drive time of the electric oil pump 110 is set based on the accumulated time T, the average vehicle speed Va, the accumulated travel distance L, the hydraulic oil temperature of the automatic transmission 3, and the like.
[0059]
Specifically, as the accumulated time T or the accumulated travel distance L becomes longer, overheating of the oil-required portion is likely to occur, so the drive time is set longer. In addition, as the average vehicle speed Va increases, overheating of the oil-required part is likely to occur, so that the drive time is set longer. Furthermore, since the oil path resistance increases as the hydraulic oil temperature of the automatic transmission 3 decreases and the oil supply performance decreases, the drive time of the electric oil pump 110 is set longer. FIG. 12 is a diagram showing an example when the operation time Toil of the electric oil pump 110 is set based on the average vehicle speed Va. That is, as the average vehicle speed Va increases, the operating time Toil of the electric oil pump 110 is set longer.
[0060]
Following step S9, the line pressure, which is the entire original pressure of the hydraulic control device 7, is controlled to the pressure adjustment mode by the linear solenoid valve SLT (step S10), and all the parameters obtained in steps S4, S5, and S6 are cleared. (Step S11), and returns.
[0061]
On the other hand, if a negative determination is made in step S8, it is determined that it is not yet necessary to lubricate the oil-required portion, and the process returns as it is. On the other hand, if a negative determination is made in step S3, it is not necessary to drive the electric oil pump 110, and the routine returns. Further, when the determination in step S2 is negative, the mechanical oil pump 6 is driven by the power of the engine 1 or the motor / generator, so that the electric oil pump 110 need not be driven. Therefore, all the parameters obtained in steps S4, S5 and S6 are cleared (step S12), and the process returns. Here, the correspondence between the functional means shown in FIG. 1 and the configuration of the present invention will be described. Steps S1 to S12 correspond to the oil pump driving means of the present invention.
[0062]
Next, an example of a time chart corresponding to the control example of FIG. 1 is shown in FIG. That is, when the vehicle is not towed (that is, when the vehicle towing determination is OFF), the cumulative travel distance L is zero and the cumulative time T is also zero. For this reason, the electric oil pump is stopped. Then, at the time t1, when the towing of the vehicle is started (that is, the towing determination of the vehicle is ON), the counting of the cumulative travel distance L and the cumulative time T of the vehicle by the towing is started. Thereafter, the towing of the vehicle is continued, the accumulated travel distance L becomes longer, and the accumulated time T becomes longer.
[0063]
At time t2, the cumulative time T has not yet reached the reference value (the intermittent operation reference set in step S7), but the cumulative travel distance L is the reference value (the intermittent operation reference set in step S7). Has reached. Therefore, at time t2, the electric oil pump is driven when at least one of the reference values is achieved. With the start of driving of the electric oil pump, the cumulative travel distance L and the cumulative time T are all cleared. Then, at the time t3 when the driving time Toil has elapsed from the time t2, the electric oil pump is stopped again, and thereafter the cumulative travel distance L and the cumulative time T are counted as long as the vehicle is being pulled.
[0064]
As described above, according to this embodiment, even when the vehicle is towed and the power of the wheel 96A is transmitted to the automatic transmission 3, the oil-required portion that moves relative to the power transmission, specifically, various types The oil can be forcibly supplied to the meshing portion of the two gears to improve the lubrication performance. Therefore, heat generation and wear of a portion that moves relative to the input of power when the vehicle is towed are suppressed, and the durability is improved.
[0065]
Further, the electric oil pump 110 is intermittently driven based on various parameters such as the cumulative travel distance L, the average vehicle speed Va, the cumulative time T, and the hydraulic oil temperature of the automatic transmission 3. For this reason, the power consumption of the electric motor 110A that drives the electric oil pump 110 is suppressed. Further, even when the electric motor 110A is a motor having a brush for energization, the intermittent wear of the electric motor 110A suppresses the wear of the brush and improves its durability.
[0066]
Furthermore, according to this embodiment, the necessary oil condition, that is, the necessary condition for lubrication and cooling, is indirectly determined based on parameters such as the accumulated travel distance L, the average vehicle speed Va, and the accumulated time T. The electric oil pump 110 is intermittently driven according to the determination result, and the intermittent operation time is determined. For this reason, it is possible to forcibly supply oil in accordance with the oil required state of the oil required portion. Therefore, useless driving of the electric motor 110A can be avoided and power consumption can be further reduced. When the drive of the electric oil pump 110 is controlled according to the operating oil temperature of the automatic transmission 3, the oil is supplied according to the viscosity of the oil. Therefore, it is possible to ensure the supply state of the oil in accordance with the oil supply responsiveness, and the lubricity of the oil-required portion is further improved.
[0067]
【The invention's effect】
As described above, according to the first aspect of the present invention, with respect to the transmission device in which the power of the wheels is input when the vehicle is towed. The first o Oil can be supplied by an oil pump to improve its lubricating performance. Therefore, heat generation and wear of the transmission are suppressed, and the durability is improved.
[0068]
According to the first aspect of the present invention, the first oil pump is driven intermittently. The power consumption of the electric motor for driving the oil pump can be reduced. Claim Item 2 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and since the oil is supplied according to the oil necessary state in the transmission, unnecessary driving of the electric motor is avoided. Therefore, power consumption can be further reduced.
[0069]
Claim Item 3 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and the oil supply state is controlled based on the travel distance of the towed vehicle. Therefore, useless driving of the electric motor can be avoided and power consumption can be further reduced. Claim Item 4 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and the oil supply state is controlled based on the time for which the vehicle is towed. Therefore, useless driving of the electric motor can be avoided, and power consumption can be further reduced.
[0070]
Claim Item 5 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and the oil supply state is controlled based on the time when the vehicle is towed and the vehicle speed of the towed vehicle. Therefore, useless driving of the electric motor can be avoided and power consumption can be further reduced. Claim Item 6 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and since the oil supply time is controlled, useless driving of the electric motor can be avoided and the power consumption can be further reduced.
[0071]
Claim Item 7 According to the invention, the same effect as that of the invention of claim 1 can be obtained, and the supply of oil is controlled according to the viscosity of the oil. Therefore, it is possible to ensure an oil supply state in accordance with the oil supply response, and the lubrication performance is further improved.
[0072]
Claim According to the invention of claim 8, the claims 1 to 7 of In addition to the same effect as any of the above, the driving force source is stopped and the power of this driving force source 2nd o Even when the vehicle pump cannot be driven, The first oil pump is driven and transmitted Oil is supplied to the oil required part of the transmission device, and the lubricity of the transmission device can be ensured.
[Brief description of the drawings]
FIG. 1 is a flowchart illustrating an example of control executed by a control device for a vehicle oil pump according to the present invention.
FIG. 2 is a block diagram schematically showing an example of a power train and a control system of a hybrid vehicle that is an application example of the present invention.
FIG. 3 is a skeleton diagram that embodies the power plant shown in FIG. 2;
4 is a chart showing engagement / release of clutches and brakes for setting each gear position of the automatic transmission of FIG. 3; FIG.
5 is a conceptual diagram showing a shift position selected by operating a shift lever that controls the automatic transmission shown in FIG. 2. FIG.
6 is a conceptual diagram showing a sport mode switch for setting / releasing a state in which the gear position of the automatic transmission shown in FIG. 2 can be changed by manual operation.
7 is a schematic diagram showing an example of a mechanism for switching between a mechanical oil pump and an electric oil pump and connecting to a primary regulator valve in the hybrid vehicle of FIG. 2. FIG.
FIG. 8 is a diagram showing input / output signals in an integrated control apparatus according to an example of the present invention.
FIG. 9 is a map collectively showing a control mode for controlling driving and stopping of the engine and motor / generator of the hybrid vehicle shown in FIG. 2 and a shift diagram for controlling a shift stage of the automatic transmission.
FIG. 10 is a two-dimensional map used when obtaining the intermittent operation time of the electric oil pump of FIG. 2 and showing an average vehicle speed and an accumulated time.
11 is a diagram used for obtaining the intermittent operation time of the electric oil pump of FIG. 2 and is a diagram showing the relationship between the average vehicle speed and the accumulated time.
12 is a diagram showing the relationship between the average vehicle speed and the driving time, which is used when obtaining the driving time of the electric oil pump of FIG. 2. FIG.
FIG. 13 is a time chart corresponding to the control example of FIG. 1;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 3 ... Automatic transmission, 5 ... Transmission mechanism, 110 ... Electric oil pump, 110A ... Electric motor, IG ... Ignition switch.

Claims (8)

The control apparatus for an oil pump for a vehicle for supplying oil to the transmission by Ri first oil pump is driving dynamic to the electric motor,
Vehicle, characterized in that when a state in which the vehicle is towed, and includes the electric motor intermittently by drive moving the first oil pump Ri by the the oil pump drive hands stage supplies oil Oil pump control device. Wherein the oil pump driving means, the vehicle oil pump according to claim 1, characterized in that it contains before Symbol function based on the oil required state of the transmission to drive the dynamic of the first oil pump Control device. The said oil pump driving means, based on the travel distance of the vehicle to be towed, control of the vehicle oil pump according to claim 1, characterized in that it contains the function to drive the first O Iruponpu apparatus. The said oil pump driving means, on the basis of the vehicle time is pulled, the control of the vehicle oil pump according to claim 1, characterized in that it contains the function to drive the first O Iruponpu apparatus. The said oil pump driving means, according to claim 1, wherein the vehicle includes a function for driving the first o Iruponpu based on the vehicle speed of the vehicle being between and traction when towed Control device for vehicle oil pump. The oil pump driving means, a control device for a vehicle oil pump according to claim 1, characterized in that it contains before Symbol function to drive the first oil pump a predetermined time. The said oil pump driving means, on the basis of the temperature before Symbol oil, control of the vehicle oil pump according to claim 1, characterized in that it includes the ability to control the drive of the first oil pump apparatus. Before SL and start-stop control device for controlling the starting and stopping of the drive power source is provided in the vehicle, separately from the second oil pump provided with the first oil pump as a hydraulic source for supplying oil to the transmission And the second oil pump can be driven by the power of the driving force source, and the oil pump driving means is in a state where the start / stop control device stops the driving force source, and 8. The function according to claim 1, further comprising: supplying oil to the transmission device by driving the first oil pump by the electric motor when the vehicle is being towed. control device for an oil pump for a vehicle of crab according.

Images