BELT CONTINUOUSLY VARIABLE TRANSMISSION AND FAILURE DETERMINATION METHOD OF THE SAME

Abstract

A transmission controller is configured to determine whether an output rotation speed sensor has a failure or not on the basis of a detected value by the output rotation speed sensor, and if the output rotation speed sensor is determined to have a failure, executes a fail-safe control which controls the pressure regulating valve such that the primary pressure becomes a predetermined high pressure regardless of the instruction pressure and inhibits a failure determination of the pressure regulating valve on the basis of a difference between the instruction pressure and a detected value by the primary pressure sensor.

Description

TECHNICAL FIELD

The present invention relates to a technique that determines a failure of such as a sensor and a solenoid valve in a belt continuously variable transmission (hereinafter referred to as “CVT”).

BACKGROUND ART

A CVT is constituted of a primary pulley and a secondary pulley whose groove widths are changeable and a belt stretched around between the primary pulley and the secondary pulley. Changing the groove widths of the respective pulleys changes contact radiuses between the belt and the respective pulleys, thus changing a speed ratio steplessly.

The groove widths of the primary pulley and the secondary pulley are changed by primary pressure and secondary pressure supplied to respective oil chambers of these pulleys. By these hydraulic pressures, the belt is sandwiched by the primary pulley and by the secondary pulley.

If a solenoid valve, which adjusts these hydraulic pressures, fails, a difference between an instruction pressure and an actual pressure becomes large; therefore, whether a failure occurs or not can be determined on the basis of the difference between the instruction pressure and the actual pressure.

Meanwhile, JP2002-228674A discloses an automatic transmission that determines whether an output rotation speed sensor of the transmission has a failure or not and when the automatic transmission determines that the output rotation speed sensor has a failure, the automatic transmission executes a predetermined fail-safe control (for example, a gear position is fixed to a third speed).

Even with the CVT, since a target speed ratio cannot be appropriately set while the output rotation speed sensor has a failure, the predetermined fail-safe control is executed in such case. For example, when all of a primary pressure solenoid valve, which adjusts primary pressure, a secondary pressure solenoid valve, which adjust secondary pressure, and further a line pressure solenoid valve, which adjusts line pressure becoming source pressure of these pressures, are normal high solenoid valves in which an output hydraulic pressure becomes the maximum relative to an input hydraulic pressure during non-energization, the fail-safe control to stop the energization to these solenoid valves is executed. This increases the respective primary pressure, secondary pressure, and line pressure and fixes the speed ratio of the CVT, thus maintaining a vehicle in a runnable state.

SUMMARY OF INVENTION

While the output rotation speed sensor has a failure, since the actual vehicle speed becomes unknown, a predetermined low vehicle speed is used as an alternative value for control, and this sets an instruction value of the primary pressure low.

However, if the output rotation speed sensor of the CVT with the configuration fails, the fail-safe control stops the energization to the respective solenoid valves and these output hydraulic pressures become the maximum. Accordingly, an increase in rotation speed of an engine increases generated hydraulic pressure of an oil pump and increases the primary pressure.

Consequently, the instruction value deviates from actual pressure and when the primary pressure solenoid valve is determined to have a failure on the basis of this difference, although the primary pressure solenoid valve does not have a failure, the primary pressure solenoid valve is determined to have a failure. In addition to the failure of the output rotation speed sensor, when the primary pressure solenoid valve is also determined to have a failure, it is determined that a failure occurs at a plurality of sites, and a fail-safe control for double failure is executed.

For example, with a CVT with a sub-transmission mechanism, the fail-safe control for double failure is a control that fixes a gear position of the sub-transmission mechanism to a second speed and performs torque down of the engine. This control aims to safely evacuate a vehicle to a safe location. The execution of this control largely affects power performance of the vehicle; therefore, the execution of such control on the basis of an erroneous determination result is not preferable in some cases.

The present invention has been made in view of such technical problem, and it is an object of the present invention to prevent an erroneous determination that a primary pressure solenoid valve has a failure while the primary pressure solenoid valve does not have a failure in the case where an output rotation speed sensor is determined to have a failure.

According to an aspect of the present invention, a belt continuously variable transmission including a pressure regulating valve configured to adjust a primary pressure supplied to a primary pulley to be an instruction pressure; a primary pressure sensor configured to detect the primary pressure; an output rotation speed sensor configured to detect an output rotation speed of the belt continuously variable transmission; and a controller is provided.

The controller is configured to determine whether the output rotation speed sensor has a failure or not on the basis of a detected value by the output rotation speed sensor; and if the output rotation speed sensor is determined to have a failure, execute a fail-safe control which controls the pressure regulating valve such that the primary pressure becomes a predetermined high pressure regardless of the instruction pressure and inhibit a failure determination of the pressure regulating valve on the basis of a difference between the instruction pressure and a detected value by the primary pressure sensor.

According to another aspect of the present invention, a failure determination method of the belt continuously variable transmission corresponding to this configuration is provided.

According to these aspects, when the output rotation speed sensor is determined to have a failure, the failure determination of the primary pressure regulation valve is not performed; therefore, the primary pressure solenoid valve is not erroneously determined to have a failure while the primary pressure regulation valve is normal.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an overall configuration diagram of a belt continuously variable transmission according to an embodiment of the present invention.

FIG. 2 is a partial schematic configuration diagram of a hydraulic control circuit.

FIG. 3 is a diagram describing a failure determination method of a solenoid valve.

FIG. 4 is a diagram illustrating a state of erroneous determination of a failure in the solenoid valve.

FIG. 5 is a flowchart illustrating a process content of a transmission controller.

DESCRIPTION OF EMBODIMENTS

The following describes an embodiment of the present invention by referring to the attached drawings.

FIG. 1 is a schematic configuration diagram of a vehicle on which a belt continuously variable transmission according to the embodiment of the present invention is mounted. This vehicle includes an engine 1 as a power source. Output rotation of the engine 1 is transmitted to driving wheels 7 via a torque converter 2, a first gear train 3, a transmission 4, a second gear train 5, and a differential gear 6. A parking mechanism 8 that mechanically unrotatably locks an output shaft of the transmission 4 in parking is disposed on the second gear train 5.

The engine 1 is an internal combustion engine such as a gasoline engine and a diesel engine. An engine controller 13 controls a rotation speed and a torque of the engine 1.

The torque converter 2 includes a lock-up clutch 2a. When the lock-up clutch 2a is engaged, slip at the torque converter 2 disappears to ensure improving transmission efficiency of the torque converter 2.

The vehicle includes an oil pump 10 driven using a part of power of the engine 1, a hydraulic control circuit 11 that regulates hydraulic pressure from the oil pump 10 to supply the hydraulic pressure to each part of the transmission 4, and a transmission controller 12 that controls the hydraulic control circuit 11.

The transmission 4 is a continuously variable transmission including a variator 20 and a sub-transmission mechanism 30 disposed in series with respect to the variator 20. “Disposed in series” means that the variator 20 and the sub-transmission mechanism 30 are disposed in series in a power transmission path from the engine 1 up to the driving wheels 7. While in this example, the sub-transmission mechanism 30 is disposed at an output side of the variator 20, the sub-transmission mechanism 30 may be disposed at the input side.

The variator 20 is a continuously variable transmission mechanism including a primary pulley 21, a secondary pulley 22, and a belt 23 stretched between the pulleys 21 and 22. The pulleys 21 and 22 include fixed conical plates 21f and 22f, movable conical plates 21m and 22m disposed in a state where sheave surfaces are opposed to the fixed conical plates 21f and 22f to form grooves with the fixed conical plates 21f and 22f, and hydraulic cylinders 21p and 22p disposed at back surfaces of the movable conical plates 21m and 22m to axially displace the movable conical plates 21m and 22m, respectively. While a metal belt, a rubber belt, a chain belt, and a similar belt can be used as the belt 23, the belt 23 is not specifically limited to them.

Adjusting hydraulic pressure (a primary pressure Ppri and a secondary pressure Psec) supplied to the pulleys 21 and 22 changes force that the belt 23 is sandwiched by the pulleys 21 and 22 to change a torque capacity (a transmissive maximum torque) of the variator 20, and changes groove widths to change contact radiuses of the belt 23 and the respective pulleys 21 and 22, thus a speed ratio of the variator 20 steplessly changes.

The sub-transmission mechanism 30 is a transmission mechanism having two stages for forward and one stage for backward. The sub-transmission mechanism 30 includes a Ravigneaux planetary gear mechanism 31 where carriers of two planetary gears are coupled, and a plurality of friction elements (a Low brake 32, a High clutch 33, and a Rev brake 34). Adjusting hydraulic pressure supplied to the friction elements 32 to 34 to change engagement states of the friction elements 32 to 34 changes a gear position of the sub-transmission mechanism 30.

The transmission controller 12 includes a storage device including a CPU, and a RAM and a ROM, input/output interfaces, and a bus that mutually couples them.

Various signals are input to the transmission controller 12 via the input/output interfaces. The input signals include the following signals:

• • A signal from an accelerator position sensor 41 that detects an accelerator position APO indicative of a manipulated variable of an accelerator pedal
  • A signal from a primary rotation speed sensor 42 that detects a primary rotation speed Npri as a rotation speed of the primary pulley 21
  • A signal from an output rotation speed sensor 43 that detects an output rotation speed of the transmission 4 (00 vehicle speed)
  • A signal from a line pressure sensor 44 that detects a line pressure PL
  • A signal from a primary pressure sensor 45 that detects the primary pressure Ppri
  • A signal from a secondary pressure sensor 46 that detects the secondary pressure Psec
  • A signal from an inhibitor switch 47 that detects a position of a select lever
  • A signal from a secondary rotation speed sensor 48 that detects a secondary rotation speed Nsec as a rotation speed of the secondary pulley 22
  • A signal indicative of operating states (the rotation speed and the torque) of engine 1 from the engine controller 13

The storage device of the transmission controller 12 stores a shift control program of the transmission 4 and a shift map used in this shift control program. The transmission controller 12 reads the shift control program stored in the storage device to cause the CPU to execute this shift control program, thus performing a predetermined arithmetic process to signals input via the input interface. The transmission controller 12 sets an instruction pressure of the hydraulic pressure supplied to each part of the transmission 4 and outputs the set instruction pressure to the hydraulic control circuit 11 via the input/output interfaces. The transmission controller 12 outputs an engine control signal (for example, a torque down signal) to the engine controller 13 as necessary.

The hydraulic control circuit 11 includes a plurality of flow paths and a plurality of hydraulic control valves. The hydraulic control circuit 11 controls the plurality of hydraulic control valves on the basis of the instruction pressure from the transmission controller 12 to switch a supply passage of the hydraulic pressure and generates the hydraulic pressure according to the instruction pressure to supply the hydraulic pressure to each part of the transmission 4. This performs a shift of the variator 20, the change of the gear position of the sub-transmission mechanism 30, capacity control of the respective friction elements 32 to 34, and an engagement or a disengagement of the lock-up clutch 2a.

FIG. 2 illustrates a part related to the shift of the variator 20 in the hydraulic control circuit 11.

A line pressure solenoid valve 61 is a drain-pressure-regulating solenoid valve that drains a part of a discharge pressure of the oil pump 10 and reduces the pressure to regulate the line pressure PL to the instruction pressure.

A primary pressure solenoid valve 62 and a secondary pressure solenoid valve 63 are drain-pressure-regulating solenoid valves that drain a part of the line pressure PL and reduce the pressure using the line pressure PL as a source pressure to regulate the primary pressure Ppri and the secondary pressure Psec to the respective instruction pressures.

The solenoid valves 61 to 63 respectively include feedback circuits 61f, 62f, and 63f that return the hydraulic pressure after the pressure regulation to the pressure regulating valves and perform the feedback control on the hydraulic pressure after the pressure regulation such that the hydraulic pressures become the instruction pressures. The instruction pressures are instructed to the solenoid valves 61 to 63 in the form of instruction currents to the solenoid valves 61 to 63. The solenoid valves 61 to 63 are normal high solenoid valves where respective output hydraulic pressures relative to input hydraulic pressures become the maximum at the instruction current of 0 mA.

With such configuration, the hydraulic control circuit 11 can independently adjust the primary pressure Ppri and the secondary pressure Psec using the line pressure PL as the source pressure.

The transmission controller 12 monitors and determines whether, for example, the sensors 41 to 48 and the solenoid valves 61 to 63 are normal or not, and when the transmission controller 12 determines that any part has a failure, the transmission controller 12 performs the fail-safe control according to the failure part.

For example, the transmission controller 12 determines whether the output rotation speed sensor 43 has a failure or not on the basis of the signal from the output rotation speed sensor 43. If the transmission controller 12 cannot obtain the signal from the output rotation speed sensor 43 or the signal has an abnormal value, it is considered that a signal line is disconnected or the sensor itself has a failure; therefore, the output rotation speed sensor 43 is determined to have a failure.

When the transmission controller 12 determines that the output rotation speed sensor 43 has a failure, the transmission controller 12 sets the instruction currents to the respective solenoid valves to 0 mA such that the output hydraulic pressure of the solenoid valves 61 to 63 relative to the input hydraulic pressure becomes the maximum regardless of the instruction pressures. That is, the transmission controller 12 cuts off the currents to the solenoid valves 61 to 63, increases the primary pressure Ppri, the secondary pressure Psec, and the line pressure PL, and fixes the speed ratio of the variator 20.

If the output rotation speed sensor 43 fails, the vehicle speed becomes unknown. Accordingly, the transmission controller 12 uses a predetermined low vehicle speed (for example, 10 km/h) as an alternative value of the detected value by the output rotation speed sensor 43 for various controls.

Regarding the solenoid valves 61 to 63, the transmission controller 12 determines whether the solenoid valves 61 to 63 have a failure or not on the basis of a difference between the instruction pressure and the detected values (the actual pressures) by sensors 51 to 53.

Specifically, as illustrated in FIG. 3, a region where a deviation between the instruction pressure and the detected value is large is preset as a failure region. When a combination of the instruction pressure and the detected value enters the failure region, the transmission controller 12 determines that the solenoid valve as the determination target has a failure.

When the transmission controller 12 determines that any of the solenoid valves 61 to 63 has a failure, the transmission controller 12 executes the fail-safe control according to the solenoid valve determined to have a failure. For example, when the transmission controller 12 determines that the primary pressure solenoid valve 62 has a failure, the transmission controller 12 sets the instruction current to the secondary pressure solenoid valve 63 to 0 mA, that is, cuts off the current to the secondary pressure solenoid valve 63 to increase the secondary pressure Psec.

When the transmission controller 12 determines that a double failure indicative of failures at a plurality of sites occurs, the transmission controller 12 executes a fail-safe control for double failure to safely evacuate the vehicle to a safe location. In this control, for example, the transmission controller 12 fixes the gear position of the sub-transmission mechanism 30 to the second speed and instructs the execution of the torque down of the engine 1 to the engine controller 13.

However, if the failure determination of the primary pressure solenoid valve 62 on the basis of the difference between the instruction pressure and the detected value is executed when the output rotation speed sensor 43 is determined to have a failure and the fail-safe control is executed, although the primary pressure solenoid valve 62 does not have a failure, the primary pressure solenoid valve 62 is erroneously determined to have a failure and the fail-safe control for double failure is possibly executed.

FIG. 4 illustrates the state in such case.

When the output rotation speed sensor 43 is determined to have a failure and the fail-safe control is executed, the instruction currents to the respective solenoids are set to 0 mA such that the output hydraulic pressures of the solenoid valves 61 to 63 relative to the input hydraulic pressures become the maximum regardless of the instruction pressures to increase the line pressure PL, the primary pressure Ppri, and the secondary pressure Psec.

Meanwhile, since the vehicle speed is unknown, the use of the predetermined low vehicle speed for control is performed at the same time. This sets the low hydraulic pressure according to the predetermined low vehicle speed as the instruction pressure of the primary pressure Ppri (a point X in the drawing).

In this situation, if the rotation speed of the engine 1 increases and thus the generated hydraulic pressure of the oil pump 10 increases, while the primary pressure Ppri becomes high according to this, the instruction pressure of the primary pressure Ppri remains to be the low value corresponding to the predetermined low vehicle speed (a point Y in the drawing).

For this reason, the detected value deviates from the instruction pressure and the combination of the instruction pressure and the detected value exits a normal region and enters the failure region; therefore, the normal primary pressure solenoid valve 62 is also determined to have a failure.

When the primary pressure solenoid valve 62 is also determined to have a failure subsequent to the output rotation speed sensor 43, the fail-safe control for double failure is executed. However, as described above, since the fail-safe control for double failure is the fail-safe control putting emphasis on safety, the fail-safe control for double failure largely affects the running performance and the execution of such control on the basis of the erroneous determination result is not preferable.

Therefore, when the transmission controller 12 determines that the output rotation speed sensor 43 has a failure, the transmission controller 12 inhibits the failure determination of the primary pressure sensor on the basis of the difference between the instruction pressure and the detected pressure.

FIG. 5 illustrates a process content of the transmission controller 12 for such operation.

According to this, when the transmission controller 12 determines that the output rotation speed sensor 43 has a failure, the transmission controller 12 advances the process from Step S1 to Steps S2 and S3. Then, the transmission controller 12 executes the fail-safe control (the instruction currents of the solenoid valves 61 to 63=0 mA) when the output rotation speed sensor 43 has a failure and inhibits the failure determination of the primary pressure solenoid valve 62.

Thus, when the output rotation speed sensor 43 is determined to have a failure, the failure determination of the primary pressure solenoid valve 62 is not performed; therefore, the primary pressure solenoid valve 62 is not erroneously determined to have a failure while the primary pressure solenoid valve 62 is normal.

Accordingly, the state is not determined as the double failure, the fail-safe control for double failure is not executed, the sub-transmission mechanism 30 is not fixed to the second speed, and the running performance does not largely lower.

The transmission controller 12 executes the fail-safe control according to the failure site as described above. When an ignition key is operated to be off, the fail-safe control in execution is terminated at the timing. In the case where the ignition key is turned on again and the vehicle leaves again, whether the sensors, the solenoid valves, or similar devices have a failure or not is determined again. When it is determined again that a failure occurs, the fail-safe control is executed again.

This is because there may be a case where a failure has been solved at the time point at which the ignition key is turned on again. In this case, the execution of the unnecessary fail-safe control and deterioration of the running performance of the vehicle at restart can be prevented.

The embodiment of the present invention described above is merely illustration of one application example of the present invention and not of the nature to limit the technical scope of the present invention to the specific constructions of the above embodiment.

For example, while the embodiment sets the instruction currents to the respective solenoid valves 61 to 63 to 0 mA corresponding to the maximum pressure when the output rotation speed sensor 43 is determined to have a failure, it is only necessary that the line pressure PL, the primary pressure Ppri, and the secondary pressure Psec can be increased up to the predetermined high pressures and the speed ratio can be fixed. Accordingly, the instruction current is not limited to 0 mA corresponding to the maximum pressure and may be a value larger than 0 mA.

The present application claims a priority of Japanese Patent Application No. 2015-179519 filed with the Japan Patent Office on Sep. 11, 2015, all the contents of which are hereby incorporated by reference.

Claims

1. A belt continuously variable transmission comprising: a pressure regulating valve configured to adjust a primary pressure supplied to a primary pulley to be an instruction pressure;a primary pressure sensor configured to detect the primary pressure;an output rotation speed sensor configured to detect an output rotation speed of the belt continuously variable transmission; anda controller, whereinthe controller is configured to: determine whether the output rotation speed sensor has a failure or not on the basis of a detected value by the output rotation speed sensor; andif the output rotation speed sensor is determined to have a failure, execute a fail-safe control which controls the pressure regulating valve such that the primary pressure becomes a predetermined high pressure regardless of the instruction pressure and inhibit a failure determination of the pressure regulating valve on the basis of a difference between the instruction pressure and a detected value by the primary pressure sensor.

2. The belt continuously variable transmission according to claim 1, further comprising a sub-transmission mechanism that has a first gear position and a second gear position, the second gear position having a speed ratio smaller than the first gear position, whereinthe controller is further configured such that if the output rotation speed sensor and the pressure regulating valve are determined to have a failure, the controller fixes the gear position of the sub-transmission mechanism to the second gear position.

3. The belt continuously variable transmission according to claim 1, wherein the controller is further configured such that if an ignition key turns off, the controller cancels the fail-safe control.

4. A failure determination method of a belt continuously variable transmission that includes a pressure regulating valve configured to adjust a primary pressure supplied to a primary pulley to be an instruction pressure, a primary pressure sensor configured to detect the primary pressure, and an output rotation speed sensor configured to detect an output rotation speed of the belt continuously variable transmission, the failure determination method comprising: determining whether the output rotation speed sensor has a failure or not on the basis of a detected value by the output rotation speed sensor; andif the output rotation speed sensor is determined to have a failure, executing a fail-safe control which controls the pressure regulating valve such that the primary pressure becomes a predetermined high pressure regardless of the instruction pressure and inhibiting a failure determination of the pressure regulating valve on the basis of a difference between the instruction pressure and a detected value by the primary pressure sensor.

5. A belt continuously variable transmission comprising: a pressure regulating valve configured to adjust a primary pressure supplied to a primary pulley to be an instruction pressure;a primary pressure sensor configured to detect the primary pressure;an output rotation speed sensor configured to detect an output rotation speed of the belt continuously variable transmission;means for determining whether the output rotation speed sensor has a failure or not on the basis of a detected value by the output rotation speed sensor; andmeans for, if the output rotation speed sensor is determined to have a failure, executing a fail-safe control which controls the pressure regulating valve such that the primary pressure becomes a predetermined high pressure regardless of the instruction pressure and inhibiting a failure determination of the pressure regulating valve on the basis of a difference between the instruction pressure and a detected value by the primary pressure sensor.