JP3691469B2 - Hybrid vehicle hydraulic circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure the working hydraulic pressure of a transmission while an engine is stopped by certainly operating an electric oil pump. <P>SOLUTION: A hydraulic circuit 30 to feed the hydraulic pressure to a transmission of a hybrid vehicle having an engine 2 and a motor as power sources comprise a mechanical oil pump 11 to be operated by at least one of the driving force of the engine 2 and the motor, an electric oil pump 12 to be operated under a predetermined condition, a hydraulic pressure control circuit 20 to feed the hydraulic pressure to the transmission, a discharge pipe 34 to feed the hydraulic pressure to the hydraulic pressure control circuit 20 from the mechanical oil pump 11, a discharge pipe 36 to feed the hydraulic pressure from the electric oil pump 12 to the discharge pipe 34, a non-return valve 37 disposed in the discharge pipe 36, and a feed pipe 38 to feed oil in an oil sump 22 provided in the hydraulic pressure control circuit 20 to the electric oil pump 12. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hydraulic circuit of a hybrid vehicle using an engine and a motor as drive sources.
[0002]
[Prior art]
In recent years, a motor capable of generating power with an engine (hereinafter referred to as a motor / generator) is connected to a power transmission mechanism connected to a driving wheel of a vehicle for the purpose of saving fuel for driving the engine and reducing exhaust gas generated by fuel combustion. And driving assistance by the motor / generator as necessary during traveling, and also the power input from the driving wheels during deceleration is transmitted to the motor / generator, and the motor / generator performs regenerative operation. Hybrid vehicles have been developed that convert deceleration energy into regenerative energy and charge the power storage device as electrical energy.
[0003]
When such a hybrid vehicle employs a hydraulically operated automatic transmission, the hydraulic pressure of the transmission mechanism in the automatic transmission is ensured by a hydraulic pump driven by the engine. When the engine stops, the hydraulic pump also stops, so that the operating hydraulic pressure of the transmission mechanism cannot be secured.
Therefore, a hybrid vehicle equipped with an electric oil pump separately from the hydraulic pump driven by the engine (hereinafter referred to as a mechanical oil pump) has been developed so that the operating hydraulic pressure of the transmission mechanism can be secured even when the engine is stopped. (See JP 10-324177 A).
[0004]
[Problems to be solved by the invention]
However, in a conventional hybrid vehicle equipped with a mechanical oil pump and an electric oil pump, air is mixed into the suction-side oil passage of the electric oil pump while the electric oil pump is stopped, and the mechanical oil pump is stopped. When trying to operate the electric oil pump, there was a problem that a suction failure occurred and the hydraulic pressure did not rise easily.
Accordingly, the present invention provides a hydraulic circuit for a hybrid vehicle that can ensure the operating hydraulic pressure of the transmission while the engine is stopped by reliably operating the electric oil pump.
[0005]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 includes an engine (for example, an engine 2 in an embodiment described later) and a motor (for example, a motor / generator 3 in an embodiment described later) as power sources. A hybrid vehicle (for example, a hybrid vehicle in an embodiment to be described later) that transmits the power of at least one of the engine and the motor to a transmission (for example, a multi-stage automatic transmission 6 in an embodiment to be described later) to be a driving force of the vehicle. 1) a mechanical oil pump (for example, a hydraulic circuit 30 in an embodiment to be described later) that is operated by at least one of the driving force of the engine and the motor. For example, a mechanical oil pump 11) according to an embodiment to be described later is set in advance. An electric oil pump (for example, an electric oil pump 12 in an embodiment to be described later) operated under the conditions, and a hydraulic control circuit for supplying hydraulic pressure to the transmission (for example, an oil pressure control circuit 20 in an embodiment to be described later) A first oil passage (for example, a discharge pipe 34 in an embodiment to be described later) that makes it possible to supply hydraulic pressure from the mechanical oil pump to the hydraulic control circuit, and the first oil passage from the electric oil pump A second oil passage (for example, a discharge pipe 36 in an embodiment to be described later) and a backflow prevention means (for example, reverse in an embodiment to be described later) provided in the second oil passage. a check valve 37), the first oil is placed in a higher position than the electric oil pump provided in the hydraulic control circuit reservoir (e.g., ball oil in the embodiments described below 22) Oil said electric oil pump drain port (e.g., the third oil passage that can be supplied to the drain port 12c) in the embodiment described below (for example, the supply pipe 38 in the embodiment described below), The suction side oil passage of the mechanical oil pump and the suction side oil passage of the electric oil pump are connected, and the oil in the second oil reservoir (for example, the oil pan 31 in an embodiment described later) is supplied to the mechanical type. An oil pump and a suction-side oil passage that can be supplied to the electric oil pump (for example, suction pipes 33 and 35 in the embodiments described later) are provided.
[0006]
With this configuration, even when the mechanical oil pump cannot be operated while the engine is stopped, the electric oil pump can supply the necessary hydraulic pressure to the hydraulic control circuit. Further, even when air is mixed in the suction side oil passage of the electric oil pump, the oil in the first oil sump can be supplied to the electric oil pump through the third oil passage. The oil pressure can be reliably raised at the start of the pump.
[0007]
In addition, even if a negative pressure is generated in the suction-side oil passage of the mechanical oil pump during the operation of the mechanical oil pump, the mechanical oil pump supplies the oil in the first oil reservoir via the suction-side oil passage of the electric oil pump. The suction side oil passage can be introduced. Further, it is possible to prevent air from entering from the drain port of the electric oil pump.
[0008]
The invention according to claim 2 includes an engine (for example, an engine 2 in an embodiment described later) and a motor (for example, a motor / generator 3 in an embodiment described later) as power sources, and at least one of the engine and the motor. Is transmitted to a transmission (for example, a multi-stage automatic transmission 6 in an embodiment to be described later) and hydraulic pressure is applied to the transmission of a hybrid vehicle (for example, a hybrid vehicle 1 in an embodiment to be described later). In a hydraulic circuit (for example, a hydraulic circuit 30 in an embodiment to be described later), a mechanical oil pump (for example, in an embodiment to be described later) that is operated by a driving force of at least one of the engine and the motor. A mechanical oil pump 11) and an electric machine that can be operated under predetermined conditions. An oil pump (for example, an electric oil pump 12 in an embodiment described later), a hydraulic control circuit (for example, a hydraulic control circuit 20 in an embodiment described later) for supplying hydraulic pressure to the transmission, and the mechanical oil pump From the first oil passage (for example, a discharge pipe 34 in an embodiment to be described later) that enables the hydraulic pressure to be supplied from the electric oil pump to the first oil passage. A second oil passage (for example, a discharge pipe 36 in an embodiment described later), a backflow preventing means (for example, a check valve 37 in an embodiment described later) provided in the second oil passage, Oil in a first oil sump (for example, an oil sump 22 in an embodiment to be described later) provided in a hydraulic control circuit and installed at a position higher than the electric oil pump is supplied to the electric motor. A third oil passage (for example, a supply pipe 38 in an embodiment to be described later) that can be supplied to a suction-side oil passage (for example, a suction pipe 35 in an embodiment to be described later) of the oil pump; The suction-side oil passage is connected to the suction-side oil passage of the electric oil pump, and oil in a second oil reservoir (for example, an oil pan 31 in an embodiment described later) is supplied to the mechanical oil pump and the electric oil. A suction-side oil passage (for example, suction pipes 33 and 35 in the embodiments described later) that can be supplied to the pump.
With this configuration, even when the mechanical oil pump cannot be operated while the engine is stopped, the electric oil pump can supply the necessary hydraulic pressure to the hydraulic control circuit. Further, even when air is mixed in the suction side oil passage of the electric oil pump, the oil in the first oil sump can be supplied to the electric oil pump through the third oil passage. The oil pressure can be reliably raised at the start of the pump. In addition, even if a negative pressure is generated in the suction-side oil passage of the mechanical oil pump during the operation of the mechanical oil pump, the mechanical oil pump supplies the oil in the first oil reservoir via the suction-side oil passage of the electric oil pump. The suction side oil passage can be introduced. In addition, since the third oil passage supplies the oil in the first oil reservoir to the suction-side oil passage of the electric oil pump, the amount of oil supplied to the electric oil pump can be increased.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a hydraulic circuit for a hybrid vehicle according to the present invention will be described below with reference to the drawings of FIGS.
FIG. 1 is a schematic configuration diagram of a power transmission system of a hybrid vehicle 1 including a hydraulic circuit according to the present invention.
In this hybrid vehicle 1, an engine 2 and a motor (hereinafter referred to as “motor / generator”) 3 that can generate power are directly connected, and at least one of the power of the engine 2 and the motor / generator 3 is torque provided with a lock-up clutch 4. It is configured to be transmitted to the drive wheels W of the vehicle via the converter 5 and the multistage automatic transmission 6.
[0010]
The engine 2 is a multi-cylinder reciprocating engine, and includes a fuel injection / ignition control device 7 that performs fuel injection control and injection fuel ignition control for each cylinder. The operation of the fuel injection / ignition control device 7 is controlled by the ECU 8, and automatic stop / start control (so-called idle stop control) of the engine 2 is performed under predetermined conditions. Therefore, the ECU 8 includes a vehicle speed sensor for detecting the vehicle speed, an engine speed sensor for detecting the engine speed, a shift position sensor for detecting the shift position of the transmission 6, and a brake switch for detecting whether or not the brake pedal has been depressed. An output signal is input from an accelerator pedal sensor that detects the amount of depression of the accelerator pedal, a remaining capacity sensor that detects the remaining capacity of the battery 10 (not shown), and the like. In this embodiment, the fuel injection / ignition control device 7 and the ECU 8 constitute an engine automatic stop / start control means for automatically stopping and starting the engine 2 under predetermined conditions.
[0011]
The torque converter 5 transmits torque between the output shaft of the motor / generator 3 and the input shaft of the transmission 6 through a fluid in a state in which the lock-up clutch 4 is released. When engaged, the output shaft of the motor / generator 3 and the input shaft of the transmission 6 are substantially directly connected, and torque is transmitted directly between the output shaft and the input shaft regardless of the fluid. Done. Engagement / release of the lockup clutch 4 and shifting of the transmission 6 are performed by hydraulic control in the hydraulic control circuit 20 in accordance with the driving state of the vehicle.
[0012]
When the driving force is transmitted from the driving wheel W side to the motor / generator 3 side when the hybrid vehicle 1 is decelerated, the motor / generator 3 functions as a generator to generate a so-called regenerative braking force, thereby reducing the kinetic energy of the vehicle body. It collects as electric energy and charges the battery 10 via a power drive unit (PDU) 9. The regenerative output at this time is controlled by the ECU 8 via the PDU 9.
The motor / generator 3 is driven while consuming electric energy charged in the battery 10 and is controlled by the ECU 8 via the PDU 9. A capacitor may be used instead of the battery 10.
[0013]
The hybrid vehicle 1 also includes a mechanical oil pump 11 and an electric oil pump 12 as a hydraulic pressure supply source to the hydraulic control circuit 20. The mechanical oil pump 11 is connected to the output shaft of the engine 2 and is operated by the driving force of the engine 2 or the motor / generator 3. 1 schematically illustrates the configuration of the power transmission system, the mechanical oil pump 11 is disposed immediately next to the engine 2. However, in actuality, the mechanical oil pump 11 is not included in the transmission 6. And the torque converter 5.
On the other hand, the electric oil pump 12 is operated by an electric motor (drive motor) 13, and the pump driver 14 supplies the electric motor 13 with the electric power of the 12-volt battery 15. The electric oil pump 12 is controlled to operate when the engine 2 and the motor / generator 3 are stopped and the mechanical oil pump 11 cannot be operated. That is, when the pump driver 14 receives an engine stop command signal from the ECU 8, the pump driver 14 starts the electric oil pump 12, and then stops the electric oil pump 12 under a predetermined condition. The engine 2 is stopped, for example, when the vehicle speed is equal to or lower than a predetermined speed or the engine speed is equal to or lower than the predetermined speed, the accelerator pedal depression amount is “0”, the brake switch is “ON”, and the remaining capacity of the battery 10 is a predetermined value. As described above, it is permitted when all the conditions such as the shift position of the transmission 6 and the hydraulic control state of the transmission 6 are satisfied, and the engine stop command signal is output from the ECU 8 to the pump driver 14. The electric oil pump 12 is stopped when the engine 2 is started, the operating pressure of the mechanical oil pump 11 is applied, and the line pressure becomes equal to or higher than the threshold value.
[0014]
Next, a hydraulic circuit 30 that supplies hydraulic pressure to the transmission 6 will be described with reference to FIG. The suction port 11a of the mechanical oil pump 11 is connected to a strainer 32 disposed in the oil pan 31 by a suction pipe 33 (suction side oil passage), and the discharge port 11b of the mechanical oil pump 11 is connected to a discharge pipe (first pipe). An oil passage) 34 is connected to the hydraulic control circuit 20.
The suction port 12 a of the electric oil pump 12 is connected to the suction pipe 33 by a suction pipe (suction side oil passage) 35, and the discharge port 12 b of the electric oil pump 12 is connected to the discharge pipe 34 by a discharge pipe (second oil passage) 36. It is connected. The discharge pipe 36 is a check valve (a backflow prevention means) that permits the flow of oil from the discharge port 12b of the electric oil pump 12 toward the discharge pipe 34 and blocks the flow of oil from the discharge pipe 34 to the discharge port 12b. 37 is provided.
[0015]
The hydraulic control circuit 20 includes a lubrication circuit 21 for supplying oil to a bearing portion or the like of the transmission 6 and an oil reservoir 22 for receiving the oil discharged from the lubrication circuit 21. Although not shown, the hydraulic control circuit 20 includes a shift hydraulic control circuit for changing the gear position of the transmission 6, and the like. Hydraulic pressure is supplied from the discharge pipe 34. A supply pipe (third oil passage) 38 connected to the bottom of the oil reservoir 22 is connected to the drain port 12 c of the electric oil pump 12. The oil sump 22 is installed at a position higher than the mechanical oil pump 11 and the electric oil pump 12, and the capacity of the oil sump 22 is set so that the oil discharged from the lubrication circuit 21 is always accumulated. Yes.
[0016]
Next, the operation of the hydraulic circuit 30 of the hybrid vehicle 1 will be described.
As described above, in the hybrid vehicle 1, when the mechanical oil pump 11 is operated by the engine 2 or the motor / generator 3, the oil in the oil pan 31 passes from the strainer 32 through the suction pipe 33 to mechanical oil. It is sucked into the pump 11, boosted by the mechanical oil pump 11, passes through the discharge pipe 34, and is supplied to the hydraulic control circuit 20. At this time, the check valve 37 prevents the oil boosted by the mechanical oil pump 11 from flowing through the discharge pipe 36 to the electric oil pump 12 side.
[0017]
When the engine stop command signal is output from the ECU 8 to the pump driver 14 and the electric oil pump 12 is activated, the oil in the oil pan 31 is sucked into the electric oil pump 12 from the strainer 32 through the suction pipe 33 and the suction pipe 35. The pressure is increased by the electric oil pump 12 and supplied to the hydraulic control circuit 20 through the discharge pipe 36 and the discharge pipe 34. Therefore, the required oil pressure can be supplied to the hydraulic control circuit 20 by the electric oil pump 12 even when the engine 2 is stopped. As a result, it is possible to prevent a delay in the rise of the hydraulic pressure when the engine 2 is restarted, and to prevent a start response delay.
[0018]
By the way, when the electric oil pump 12 is started, if air is mixed in the suction pipe 35, the oil in the oil pan 31 cannot be sucked from the strainer 32. In this hydraulic circuit 30, the drain port of the electric oil pump 12 Since 12c is connected to the oil sump 22 by the supply pipe 38, the oil in the oil sump 22 can be supplied from the drain port 12c to the electric oil pump 12 through the supply pipe 38 even in such a case, and the required hydraulic pressure Can be supplied to the hydraulic control circuit 20.
[0019]
Further, since the suction port 11a of the mechanical oil pump 11 and the suction port 12a of the electric oil pump 12 communicate with each other through the suction pipe 33 and the suction pipe 35, the engine 2 or the motor 2 is operated when the electric oil pump 12 is stopped. When the mechanical oil pump 11 is operated by the generator 3 and negative pressure is generated in the suction pipe 33, if the drain port 12c of the electric oil pump 12 is open to the atmosphere, air is sucked from the drain port 12c. However, in this hydraulic circuit 30, since the drain port 12 c of the electric oil pump 12 is connected to the oil reservoir 22, even if negative pressure is generated in the suction pipe 33, the oil in the oil reservoir 22 is supplied to the supply pipe 38 and the drain. Air is sucked into the suction pipe 33 through the port 12c, the electric oil pump 12, and the suction pipe 35, and the air It is possible to prevent contamination. Therefore, the hydraulic pressure rises quickly when the mechanical oil pump 11 is started.
[0020]
[Other Embodiments]
The present invention is not limited to the embodiment described above.
For example, in the above-described embodiment, the hybrid vehicle in which the engine and the motor / generator are directly connected has been described. However, the engine and the motor / generator are connected in parallel, and the vehicle is driven by one or both of the driving forces. The present invention can also be applied to the hybrid vehicle 1 that drives the vehicle.
In the above-described embodiment, the oil reservoir is connected to the drain port of the electric oil pump. However, the oil reservoir is connected to the suction oil passage (suction pipe 35) of the electric oil pump so as to increase the capacity and supply amount of the oil reservoir. May be.
[0021]
【The invention's effect】
As described above, according to the first aspect of the present invention, the hydraulic pressure required for the hydraulic control circuit can be supplied by the electric oil pump even when the mechanical oil pump cannot be operated while the engine is stopped. . Moreover, even when air is mixed in the suction-side oil passage of the electric oil pump, the oil in the first oil sump can be supplied to the electric oil pump via the third oil passage. It is possible to reliably start up the hydraulic pressure when starting up. Therefore, it is possible to prevent a delay in the rise of the hydraulic pressure when the engine is restarted, and an excellent effect is obtained that a delay in the start response of the vehicle can be prevented.
[0022]
In addition, even if a negative pressure is generated in the suction-side oil passage of the mechanical oil pump during the operation of the mechanical oil pump, the mechanical oil pump supplies the oil in the first oil reservoir via the suction-side oil passage of the electric oil pump. Therefore, there is an effect that the hydraulic pressure rises quickly when the mechanical oil pump is started.
[0023]
Furthermore, even if negative pressure is generated in the suction side oil passage of the mechanical oil pump during operation of the mechanical oil pump, it is possible to prevent air from entering from the drain port of the electric oil pump. There is an effect that hydraulic pressure rises quickly at the start of the pump.
According to the second aspect of the present invention, the hydraulic pressure required for the hydraulic control circuit can be supplied by the electric oil pump even when the mechanical oil pump cannot be operated while the engine is stopped. Moreover, even when air is mixed in the suction-side oil passage of the electric oil pump, the oil in the first oil sump can be supplied to the electric oil pump via the third oil passage. It is possible to reliably start up the hydraulic pressure when starting up. Therefore, it is possible to prevent a delay in the rise of the hydraulic pressure when the engine is restarted, and an excellent effect is obtained that a delay in the start response of the vehicle can be prevented.
In addition, even if a negative pressure is generated in the suction-side oil passage of the mechanical oil pump during the operation of the mechanical oil pump, the mechanical oil pump supplies the oil in the first oil reservoir via the suction-side oil passage of the electric oil pump. Therefore, there is an effect that the hydraulic pressure rises quickly when the mechanical oil pump is started.
Further, since the third oil passage supplies the oil in the first oil sump to the suction-side oil passage of the electric oil pump, the amount of oil supplied to the electric oil pump can be increased.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an embodiment of a hybrid vehicle including a hydraulic circuit according to the present invention.
FIG. 2 is a hydraulic circuit diagram in the embodiment.
[Explanation of symbols]
1 Hybrid vehicle 2 Engine 3 Motor generator (motor)
6 Multi-speed automatic transmission (transmission)
11 Mechanical oil pump 12 Electric oil pump 12c Drain port 20 Hydraulic control circuit 22 Oil reservoir 30 Hydraulic circuit 34 Discharge pipe (first oil passage)
36 Discharge pipe (second oil passage)
37 Check valve (back flow prevention means)
38 Supply pipe (third oil passage)
33 Suction pipe (suction side oil passage of mechanical oil pump)
35 Suction pipe (suction side oil passage of electric oil pump)

Claims (2)

In a hydraulic circuit that supplies an oil pressure to the transmission of a hybrid vehicle that includes an engine and a motor as a power source and transmits power of at least one of the engine and the motor to the transmission to be a driving force of the vehicle,
A mechanical oil pump that is operated by a driving force of at least one of the engine and the motor;
An electric oil pump operated under predetermined conditions;
A hydraulic control circuit for supplying hydraulic pressure to the transmission;
A first oil passage capable of supplying hydraulic pressure from the mechanical oil pump to the hydraulic control circuit;
A second oil passage capable of supplying hydraulic pressure from the electric oil pump to the first oil passage;
Backflow prevention means provided in the second oil passage;
A third oil passage that is provided in the hydraulic control circuit and that can be supplied to a drain port of the electric oil pump from a first oil sump installed at a position higher than the electric oil pump;
The suction side oil passage of the mechanical oil pump and the suction side oil passage of the electric oil pump are connected to enable the oil in the second oil reservoir to be supplied to the mechanical oil pump and the electric oil pump. Side oil passage,
A hydraulic circuit for a hybrid vehicle, comprising: In a hydraulic circuit that supplies an oil pressure to the transmission of a hybrid vehicle that includes an engine and a motor as a power source and transmits the power of at least one of the engine and the motor to the transmission to be a driving force of the vehicle,
A mechanical oil pump that is operated by a driving force of at least one of the engine and the motor;
An electric oil pump operated under predetermined conditions;
A hydraulic control circuit for supplying hydraulic pressure to the transmission;
A first oil passage capable of supplying hydraulic pressure from the mechanical oil pump to the hydraulic control circuit;
A second oil passage capable of supplying hydraulic pressure from the electric oil pump to the first oil passage;
Backflow prevention means provided in the second oil passage;
A third oil passage that is provided in the hydraulic control circuit and that can supply oil in a first oil sump installed at a position higher than the electric oil pump to a suction-side oil passage of the electric oil pump;
The suction side oil passage of the mechanical oil pump and the suction side oil passage of the electric oil pump are connected so that the oil in the second oil sump can be supplied to the mechanical oil pump and the electric oil pump. Side oil passage,
A hydraulic circuit for a hybrid vehicle, comprising:

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