JP2012163198A - Automatic transmission control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve responsiveness of an automatic transmission in range switching.SOLUTION: If a driver operates a shift control part 31, a range switching control device 35 controls a motor 33 to switch a range of the automatic transmission 2 to a target range. The range switching control device 35, before the automatic transmission 2 is actually switched to the target range, transmits a target range signal TR to a speed change control device 36. Upon receiving the target range signal TR, the speed change control device 36 predicts progress of range switching by the range switching control device 35, sets a plan of hydraulic control and performs hydraulic control based on the plan. In a case of switching from R range to D range, the speed change control device 36 starts R pressure control before the current range signal PR shows D range. Further, the speed change control device 36 starts D pressure control without depending on the current range signal PR. The automatic transmission is early brought into an operation state corresponding to the target range.

Description

  The present invention relates to an automatic transmission control device that controls an automatic transmission in response to a driver's range switching operation.

  Patent Document 1 and Patent Document 2 disclose a control device for an automatic transmission. In these devices, an operating state (hereinafter also referred to as a range) of an automatic transmission (hereinafter also referred to as AT) is moved by an electric actuator such as a motor. This device detects a driver's range switching operation by a detector. The range control device drives a manual valve for switching the AT range by controlling a motor, and positions the manual valve in a target range. Such a range control device is also referred to as a shift-by-wire device because the AT range is switched by an electrical device without using a mechanical link mechanism.

  Further, Patent Literature 1 discloses an apparatus including a range switching control device that performs range switching and a shift control device that controls the hydraulic pressures of a plurality of engagement devices inside the AT. In this device, when the range switching is completed, a signal is transmitted from the range switching control device to the shift control device. The shift control device starts hydraulic control corresponding to the range after receiving the signal.

JP 2007-64268 A JP 2008-239072 A

  In the configuration of the prior art, there is a problem that a long waiting time is required until the AT becomes operable in the range after switching. This waiting time may include time due to multiple causes. For example, the waiting time may include a time required for the shift-by-wire device to switch the range. In addition, the waiting time may include a time required for deterministic detection of reaching the target range. The waiting time may include a time required to cancel the hydraulic control in the range before switching. Further, the waiting time may include a time required to complete the hydraulic control in the range after switching. Thus, in the prior art, a long waiting time is required from when the driver performs the switching operation to the target range until the AT becomes operable in the target range. Such a waiting time makes the driver feel poor responsiveness of the vehicle.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an automatic transmission control device that improves the response of the automatic transmission in range switching.

  The present invention employs the following technical means to achieve the above object.

  The invention according to claim 1 is a shift control comprising a range switching control device (35) for switching the range of the automatic transmission by driving an actuator, and a hydraulic control means for controlling the hydraulic pressure of the automatic transmission according to the range. A device (36) and transmission means for transmitting at least the target range from the range switching control device to the transmission control device before the range switching by the actuator is completed. The hydraulic control means depends on the range switching by the actuator. Without controlling, the hydraulic pressure is controlled based on the target range transmitted from the range switching control device to the transmission control device.

  According to this configuration, the hydraulic control executed by the hydraulic control means is executed based on the target range transmitted from the range switching control device to the transmission control device without depending on the range switching by the actuator. For this reason, there is a case where the hydraulic control can be executed without waiting for the range switching by the actuator. In some cases, hydraulic control can be executed without waiting for a fixed time required to detect the actual range. As a result, after range switching is requested, the automatic transmission can be put into an operating state corresponding to the target range at an early stage.

  In the invention according to claim 2, the hydraulic control means (164-165) executes control from the hydraulic state in the range before switching to the hydraulic state in the target range in response to transmission of the target range. Features. According to this configuration, control from the hydraulic state in the range before switching to the hydraulic state in the target range can be executed before actual switching to the target range.

  The invention according to claim 3 is characterized in that the hydraulic control means controls the hydraulic pressure providing the engaged state to the hydraulic pressure providing the non-engaged state in response to transmission of the target range. According to this configuration, the control from the hydraulic pressure that provides the engaged state in the range before switching to the hydraulic pressure that provides the non-engaged state in the target range can be executed before the actual switching to the target range.

  According to a fourth aspect of the present invention, when the hydraulic pressure control means is switching from the R range to the D range, the R pressure control for reducing the R pressure in the R range before switching in response to transmission of the target range. Means (164-165) are provided. According to this configuration, when switching from the R range to the D range, it is possible to execute and start the R pressure control without waiting for completion of switching to the D range.

  The invention according to claim 5 is characterized in that the hydraulic control means controls the hydraulic pressure that provides the disengaged state to the hydraulic pressure that provides the engaged state in response to transmission of the target range. According to this configuration, control from the hydraulic pressure that provides the disengaged state in the range before switching to the hydraulic pressure that provides the engaged state in the target range can be performed before actual switching to the target range.

  According to the sixth aspect of the present invention, when the hydraulic control means is switching from the R range to the D range, or switching from the P range to the D range, in response to transmission of the target range, The D pressure in the range is increased. According to this configuration, when switching from the R range or the P range to the D range, it is possible to execute and start the D pressure control without waiting for completion of the switching to the D range.

  The invention according to claim 7 is characterized in that the hydraulic control means further includes line pressure control means (261-264, 271-274) for increasing the line pressure in response to transmission of the target range. . According to this configuration, the line pressure control can be executed and the increase of the D pressure can be promoted without waiting for completion of switching to the D range.

  The invention according to claim 8 further predicts a time (T2) when the range of the automatic transmission is switched to the target range, and planning means (163, 173) for planning the control of the hydraulic pressure based on the predicted time. , 261, 271), and the hydraulic control means (164-168, 174-176, 262-264, 272-274) are configured to control the hydraulic pressure based on the plan.

  According to this configuration, the hydraulic control executed by the hydraulic control unit is planned by the planning unit. Moreover, the planning means predicts the time when the range of the automatic transmission is switched to the target range. Then, hydraulic control is planned based on the predicted time. For this reason, hydraulic control is planned and executed without depending on the actual range of the automatic transmission switched by the actuator. For this reason, there is a case where the hydraulic control can be executed without waiting for the range switching by the actuator. In some cases, hydraulic control can be executed without waiting for a fixed time required to detect the actual range. As a result, after range switching is requested, the automatic transmission can be put into an operating state corresponding to the target range at an early stage.

  The invention according to claim 9 predicts the time (T2) when the planning means is switched from the R range to the D range, or the switching from the P range to the D range. The control means increases the D pressure when the time elapses. According to this configuration, when switching from the R range or the P range to the D range, it is possible to execute and start the D pressure control without waiting for completion of the switching to the D range.

  According to the tenth aspect of the present invention, the planning means sets the time (T3) for increasing the line pressure based on the time (T2) when switching to the D range, and the hydraulic control means (261-264, 271-274). ) Is further characterized in that the line pressure is increased after the time (T3) when the line pressure is increased. According to this configuration, the line pressure control can be executed and the increase of the D pressure can be promoted without waiting for completion of switching to the D range.

  According to an eleventh aspect of the present invention, the shift control device includes a planning unit. According to this configuration, the shifting control device is provided with the planning means.

  According to a twelfth aspect of the present invention, the range switching control device includes planning means, and the transmission means transmits the target range and the plan from the range switching control device to the transmission control device. According to this configuration, the planning means is provided in the range switching control device.

  Note that the reference numerals in parentheses described in the claims and the above-described means indicate the correspondence with the specific means described in the embodiments described later as one aspect, and are technical terms of the present invention. It does not limit the range.

It is a block diagram which shows the control system of the automatic transmission which concerns on 1st Embodiment to which this invention is applied. It is a flowchart which shows the range switching control of 1st Embodiment. It is a flowchart which shows RD transmission control of 1st Embodiment. It is a time chart which shows the change of the state of an automatic transmission in RD range change of a 1st embodiment, (A) is change of a target range, (B) is change of the present range, (C) is The change in R pressure, (D) shows the change in D pressure. It is a flowchart which shows PD shift control of 1st Embodiment. It is a time chart which shows the change of the state of an automatic transmission in PD range change of a 1st embodiment, (A) is change of a target range, (B) is change of the present range, (C) is. The change in R pressure, (D) shows the change in D pressure. It is a flowchart which shows RD transmission control of the automatic transmission which concerns on 2nd Embodiment to which this invention is applied. It is a time chart which shows the change of the state of an automatic transmission in RD range change of a 2nd embodiment, (A) is change of a target range, (B) is change of the present range, (C) is. The change in R pressure, (D) shows the change in D pressure, and (E) shows the change in line pressure. It is a flowchart which shows PD shift control of 2nd Embodiment. It is a time chart which shows the change of the state of an automatic transmission in PD range change of a 2nd embodiment, (A) is change of a target range, (B) is change of the present range, (C) is. The change in R pressure, (D) shows the change in D pressure, and (E) shows the change in line pressure.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

(First embodiment)
FIG. 1 is a block diagram showing a control system 3 for an automatic transmission according to a first embodiment to which the present invention is applied. A control system 3 for an automatic transmission (hereinafter also referred to as AT) is mounted on a vehicle that uses the internal combustion engine 1 as at least a part of a power source. The output of the internal combustion engine 1 is decelerated by the AT 2 and transmitted to the drive wheels of the vehicle.

  AT2 provides a plurality of operating states (hereinafter also referred to as ranges). AT 2 has a manual valve for switching a plurality of operating states and a manual lever 21 for operating the manual valve. The AT 2 provides a range corresponding to the position of the manual lever 21 when the manual lever 21 is positioned at a position corresponding to each of the plurality of ranges. AT2 provides a range of at least P, R, N, and D.

  The P range is a range for stopping the vehicle and is also called a parking range. In the P range, the rotation of the drive wheels of the vehicle is prohibited by mechanically locking the output shaft of AT2.

  The R range is a range for driving the vehicle in the reverse direction, and is also called a reverse range. In the R range, an R pressure that is a hydraulic pressure for operating an R range engagement clutch as an engagement means in the AT 2 is controlled. The R pressure is controlled so that AT2 is in an operating state corresponding to the R range. When the R pressure is switched from another range to the R range, that is, when the target range is the R range, the R pressure is increased from the disengaged state in order to shift the R range engaging clutch from the non-engaged state to the engaged state. The pressure is increased to the state. On the other hand, when the R pressure is switched from the R range to another range, that is, when the target range is a range other than the R range, the R range engagement clutch is changed from the engaged state to the non-engaged state. In addition, the pressure is reduced from the pressurized state to the open state. Further, the R pressure is controlled to suppress undesirable behaviors such as vehicle vibration and shock when switching between the R range and the adjacent P range or N range. The AT 2 includes an R pressure control electromagnetic valve 22 for controlling the R pressure.

  The N range is a range that cuts off the linkage between the internal combustion engine 1 and the drive wheels of the vehicle, and is also called a neutral range.

  The D range is a range for driving the vehicle in the forward direction, and is also called a drive range. In the D range, a D pressure that is a hydraulic pressure for operating a D range engagement clutch as an engagement means in the AT 2 is controlled. The D pressure is controlled so that AT2 is in an operating state corresponding to the D range. When the D pressure is switched from another range to the D range, that is, when the target range is the D range, the D pressure is increased from the disengaged state to shift the D range engaging clutch from the non-engaged state to the engaged state. The pressure is increased to the state. On the other hand, when the D pressure is switched from the D range to another range, that is, when the target range is other than the D range, the D range engaging clutch is changed from the engaged state to the non-engaged state. In addition, the pressure is reduced from the pressurized state to the open state. Further, the D pressure is controlled so as to suppress undesirable behavior such as vehicle vibration and shock when switching between the D range and the adjacent N range. The AT 2 includes a D pressure control electromagnetic valve 23 for controlling the D pressure.

  The AT 2 can further include an L range for causing the vehicle to travel at a low speed. AT2 has a line pressure for operating a plurality of clutches provided therein. The line pressure is supplied as a hydraulic pressure source for increasing at least the D pressure. The AT 2 includes a line pressure control electromagnetic valve 24 for controlling the line pressure.

  The control system 3 includes a shift operation unit 31 that is operated by a driver, and a shift sensor 32 that detects an operation state of the shift operation unit 31. For example, the shift operation unit 31 is provided by a lever operated to a position corresponding to a plurality of ranges. The shift sensor 32 outputs an electric signal indicating an operation position of the shift operation unit 31, that is, a range desired by the driver. The shift sensor 32 provides detection means for detecting the target range.

  The control system 3 includes an electric motor 33 as an actuator that drives the manual lever 21 and adjusts the position of the manual lever 21. The motor 33 can be provided by an SR (Switched Reluctance) motor. The control system 3 includes an encoder 34 that detects the rotational position of the motor 33. The encoder 34 can be provided by an incremental type encoder.

  The control system 3 includes a range switching control device 35 (hereinafter also referred to as a range ECU (Electronic Control Unit) 35) that controls the motor 33 in response to a signal from the shift sensor 32. The range ECU 35 switches the range of AT2 by driving the actuator. The range ECU 35 is an electronic control device including a microcomputer. The range ECU 35 switches AT2 to the target range detected by the shift sensor 32. The range ECU 35 feedback-controls the motor 33 so as to drive the position of the manual lever 21 to a position corresponding to the target range. The range ECU 35 feedback-controls the rotational position of the motor 33 in accordance with a signal from the encoder 34. Based on the signal from the encoder 34, the range ECU 35 recognizes the position of the manual lever 21, that is, the current actual range (hereinafter also referred to as the current range). The range ECU 35 provides detection means for detecting the current range based on the signal from the encoder 34.

  The control system 3 controls a plurality of solenoid valves including the solenoid valves 22, 23, 24 in response to signals supplied from the range ECU 35 (hereinafter also referred to as a shift ECU (Electronic Control Unit) 36). Is provided. The shift ECU 36 includes hydraulic control means for controlling the hydraulic pressure of the AT 2 according to the range. The shift ECU 36 controls the plurality of solenoid valves so that the hydraulic pressure corresponding to the current range is supplied in the AT 2. Furthermore, in the D range, the speed change ECU 36 controls the speed ratio of AT2 in accordance with the travel speed of the vehicle, the driver's accelerator pedal operation amount and the like.

  The range ECU 35 and the shift ECU 36 include a transmission unit that transmits a signal from the range ECU 35 to the shift ECU 36. The transmission means transmits at least a target range signal TR indicating the target range before the range switching by the motor 33 under the control provided by the range ECU 35 is completed. Further, this transmission means transmits a current range signal PR indicating the current range. The shift ECU 36 controls a plurality of solenoid valves in accordance with these signals TR and PR. The hydraulic pressure control means provided by the transmission ECU 36 controls the hydraulic pressure based on the target range signal TR transmitted from the range ECU 35 to the transmission ECU 36. At this time, the hydraulic pressure control means controls the hydraulic pressure based on the target range signal TR without depending on the range switching by the motor 33. In other words, the hydraulic pressure control means does not wait for the current range signal PR indicating the current range that has been definitely detected, and based on the target range signal TR, the hydraulic pressure control for the range before switching, and after switching Start with hydraulic control for range. Range ECU 35 and transmission ECU 36 provide a control device for AT2. The control device is provided by a microcomputer including a computer-readable storage medium. The storage medium stores a computer-readable program. The storage medium can be provided by a memory. By being executed by the control device, the program causes the control device to function as the device described in this specification, and causes the control device to function so as to execute the control method described in this specification. The means provided by the control device can also be called a functional block or module that achieves a predetermined function.

  FIG. 2 is a flowchart showing the range switching control 150 executed by the range ECU 35 of the first embodiment. The range ECU 35 drives AT2 to the target range by repeating steps 151-156. In step 151, a signal from the shift sensor 32 is received. In step 152, based on the signal from the shift sensor 32, it is determined whether or not the driver is operating the shift operation unit 31 and requesting switching of the range. The loop of steps 151-152 is repeated until a range switching request is detected. If a switching request is detected, the process proceeds to step 153.

  In step 153, transmission processing is executed. In step 153, the target range signal TR and the current range signal PR are transmitted from the range ECU 35 to the transmission ECU 36. The current range signal PR is transmitted from the range ECU 35 to the transmission ECU 36 at timings other than step 153.

  In step 154, the motor 33 is energized to drive the motor 33 so that the manual lever 21 is positioned at a position corresponding to the target range. In step 155, it is determined whether or not the motor 33 has reached the target position corresponding to the target range. The loop of steps 154 to 155 is repeated until the rotational position of the motor 33 reaches the target position, that is, until the manual lever 21 reaches the target range. When the motor 33 reaches the target position, the process proceeds to step 156. In step 156, the energization to the motor 33 is stopped and the drive of the motor 33 is stopped.

  At the start of the transmission process in step 153, the range ECU 35 has not started control for driving the motor 33 toward the target range. Therefore, the target range signal TR is transmitted from the range ECU 35 to the speed change ECU 36 before starting the control of the motor 33 toward the target range. Further, at the time of the transmission processing in step 153, the motor 33 has not yet reached the target position. Therefore, the target range signal TR is transmitted from the range ECU 35 to the transmission ECU 36 before the motor 33 reaches the target position. Further, at the start of the transmission process in step 153, the manual lever 21 of AT2 is not yet positioned at the position corresponding to the target range. Therefore, the target range signal TR is transmitted from the range ECU 35 to the transmission ECU 36 before the AT 2 is switched to the target range.

  FIG. 3 is a flowchart showing the RD shift control 160 executed by the shift ECU 36 of the first embodiment. The RD shift control 160 is executed when the shift operation unit 31 is switched from the R range to the D range. In step 161, a reception process is executed. In step 161, the target range signal TR and the current range signal PR are received from the range ECU 35. In step 162, it is determined from the target range signal TR and the current range signal PR whether or not RD switching for switching from the R range to the D range has been requested. RD switching is determined when the current range signal PR is the R range and the target range signal TR is the D range. If RD switching is determined, the process proceeds to step 163.

  In step 163, a D pressure control start time T2 for controlling the D pressure is set. In step 163, the start time T2 is set by predicting the time required for the range ECU 35 to perform RD switching. The start time T2 can be set based on this measurement time by measuring in advance the time during which the range ECU 35 can complete the switching from the R range to the D range. The start time T2 can be corrected according to a parameter such as temperature. The time when step 163 is executed is immediately after the target range signal TR is transmitted from the range ECU 35 to the transmission ECU 36. At this time, the range ECU 35 has not started control for driving the motor 33 toward the target range, or the motor 33 has not yet reached the target position. Therefore, the start time T2 is set by the range ECU 35 and the speed change ECU 36 before starting the control of the motor 33 toward the target range or before the motor 33 reaches the target position. At the time of setting in step 163, the manual lever 21 of AT2 is not yet positioned at the position corresponding to the target range. Therefore, the start time T2 is set by the range ECU 35 and the shift ECU 36 before the AT2 is switched to the target range. After step 163, the shift ECU 36 executes a time measurement process for determining the arrival of the start time T2.

  Step 163 provides a planning means for predicting the time T2 when the range of AT2 is switched to the target range and planning the control of the D pressure based on the predicted time T2.

  In step 164, the R pressure is controlled. In the R pressure control, the electromagnetic valve 22 is controlled so that the R pressure changes in a predetermined pattern for RD switching. In the R pressure control, the R pressure is completely released before the D pressure is applied. This is because the D pressure cannot be applied because there is a concern about the occurrence of a shift shock or the occurrence of damage to AT2 unless the R pressure is completely removed. The R pressure control is started regardless of whether or not the range of AT2 has reached the D range. The R pressure control is triggered by the detection of RD switching in step 162. For this reason, the R pressure control is started during a period in which the current range is still in the R range. The R pressure control is started before the current range reaches the D range. The R pressure control is started before the range ECU 35 positively detects arrival at the D range based on a signal from the encoder 34. For this reason, in RD switching, R pressure control is started before AT2 is switched to the target range. As a result, the R pressure control starts early and ends early. In step 165, it is determined whether or not the R pressure control is finished. Steps 164 to 165 are repeated until the predetermined R pressure control is completed. When the R pressure control is finished, the routine proceeds to step 166.

  In response to the transmission of the target range signal TR, the hydraulic pressure control means provided by Step 164 and Step 165 changes from the hydraulic pressure state (pressurized state) of the R pressure in the R range before switching to the D range that is the target range. The pressure reduction control to the hydraulic pressure state (open state) of R pressure is executed. The hydraulic pressure control means provided by step 164 and step 165 can be called R pressure control means. The R pressure control means controls the R pressure from the hydraulic pressure that provides the engaged state to the hydraulic pressure that provides the disengaged state.

  In step 166, it is determined whether or not the start time T2 has elapsed after the completion of the R pressure control. Step 166 is repeated until the start time T2 arrives. When the start time T2 arrives, the process proceeds to step 167. In step 167, the D pressure is controlled. In the D pressure control, the electromagnetic valve 23 is controlled so that the D pressure changes in a predetermined pattern for RD switching. The D pressure control is started regardless of whether or not the range of AT2 has reached the D range. The D pressure control is triggered by the fact that RD switching is detected in step 162 and the start time T2 has elapsed. The start time T2 is set based on the time required for the range ECU 35 to complete the RD switching. Therefore, when the start time T2 arrives, AT2 is immediately after reaching the D range. For this reason, the D pressure control is started immediately after AT2 reaches the D range. The D pressure control is started without waiting for the elapse of a definite time for the range ECU 35 to detect the arrival of the D range deterministically based on a signal from the encoder 34. For this reason, in RD switching, D pressure control is started immediately after AT2 is switched to the target range. As a result, the D pressure control starts early and ends early. The D pressure cannot be applied because the original pressure is not applied unless AT2 is in the D range. In this embodiment, the time T2 when the AT2 is switched to the D range is predicted, and the D pressure control is started. Therefore, it is possible to engage the D range while suppressing the waiting time. In step 168, it is determined whether or not the D pressure control is finished. Steps 166-168 are repeated until the predetermined D pressure control is completed. When the D pressure control ends, the process ends.

  In response to the transmission of the target range signal TR, the hydraulic pressure control means provided in Step 167 and Step 168 changes the D pressure in the D range, which is the target range, from the D pressure hydraulic state (open state) in the R range before switching. The pressure increase control to the hydraulic pressure state (pressurization state) is executed. The hydraulic pressure control means provided by step 167 and step 168 can be called D pressure control means. The D pressure control means controls the D pressure from the hydraulic pressure that provides the disengaged state to the hydraulic pressure that provides the engaged state. The D pressure control means is also a hydraulic pressure control means for executing the hydraulic pressure control based on the start time T2 planned in step 163, which is a planning means.

  FIG. 4 is a time chart showing changes in the state of AT2 in the RD range switching of the first embodiment, where (A) shows the change of the target range, (B) shows the change of the current range, (C ) Shows a change in R pressure, and (D) shows a change in D pressure. By operating the shift operation unit 31, the target range is switched from the R range to the D range at time T1. The range ECU 35 moves the manual lever 21 by controlling the motor 33. As a result, the current range changes in the order of R, RN, N, ND, and D. After time T1, range ECU 35 transmits target range signal TR to transmission ECU 36. In response to this, the transmission ECU 36 starts the R pressure control. The R pressure control is executed between time T1 and time T2. The R pressure control ends while the range of AT2 passes from the R range to the N range. The shift ECU 36 sets the time T2 based on the time TD (RD) that the range ECU 35 is predicted to require for switching from the R range to the D range. Time T2 can be set as the time when time TD (RD) has elapsed from time T2. AT2 reaches the D range almost at time T2 by the range switching control by the range ECU 35. When the time T2 elapses, the D pressure control is started. The D pressure control is started at time T2 without depending on the current range signal PR. In order for the range ECU 35 to output the current range signal PR, a predetermined determination time is required after reaching the D range for processing by the range ECU 35 and filter processing for suppressing erroneous determination due to noise. However, D pressure control is started without waiting for a fixed time.

  FIG. 5 is a flowchart showing the PD shift control 170 executed by the shift ECU 36 of the first embodiment. The PD shift control 170 is executed when the shift operation unit 31 is switched from the P range to the D range. In step 171, a reception process is executed. In step 172, it is determined whether or not PD switching for switching from the P range to the D range is requested from the target range signal TR and the current range signal PR. When the current range signal PR is the P range and the target range signal TR is the D range, the PD switching is determined. If the PD switching is determined, the process proceeds to step 173.

  In step 173, a D pressure control start time T2 for controlling the D pressure is set. In step 173, the start time T2 is set by predicting the time required for the range ECU 35 to perform the PD switching. The start time T2 can be set based on this measurement time by measuring in advance the time during which the range ECU 35 can complete the switching from the P range to the D range. The start time T2 can be corrected according to a parameter such as temperature. The time when step 173 is executed is immediately after the target range signal TR is transmitted from the range ECU 35 to the transmission ECU 36. At this time, the range ECU 35 has not started control for driving the motor 33 toward the target range, or the motor 33 has not yet reached the target position. Therefore, the start time T2 is set by the range ECU 35 and the speed change ECU 36 before starting the control of the motor 33 toward the target range or before the motor 33 reaches the target position. At the time of setting in step 173, the manual lever 21 of AT2 is not yet positioned at the position corresponding to the target range. Therefore, the start time T2 is set by the range ECU 35 and the shift ECU 36 before the AT2 is switched to the target range. After step 173, the speed change ECU 36 executes a time measurement process for determining the arrival of the start time T2. In the P-D switching, the R pressure control is not executed.

  Step 173 provides a planning means for predicting the time T2 when the range of AT2 is switched to the target range and planning the control of the D pressure based on the predicted time T2.

  In step 174, it is determined whether the start time T2 has elapsed. Step 174 is repeated until the start time T2 arrives. When the start time T2 comes, the process proceeds to step 175. In step 175, the D pressure is controlled. In the D pressure control, the electromagnetic valve 23 is controlled so that the D pressure changes in a predetermined pattern for P-D switching. The D pressure control is started regardless of whether or not the range of AT2 has reached the D range. The D pressure control is triggered by the fact that the PD switch is detected in step 172 and the start time T2 has elapsed. The start time T2 is set based on the time required for the range ECU 35 to complete the PD switching. Therefore, when the start time T2 arrives, AT2 is immediately after reaching the D range. For this reason, the D pressure control is started immediately after AT2 reaches the D range. The D pressure control is started without waiting for the elapse of a definite time for the range ECU 35 to detect the arrival of the D range deterministically based on a signal from the encoder 34. For this reason, in the P-D switching, the D pressure control is started immediately after the AT 2 is switched to the target range. As a result, the D pressure control starts early and ends early. The D pressure cannot be applied because the original pressure is not applied unless AT2 is in the D range. In this embodiment, the time T2 when the AT2 is switched to the D range is predicted, and the D pressure control is started. Therefore, it is possible to engage the D range while suppressing the waiting time. In step 176, it is determined whether or not the D pressure control is finished. Steps 174 to 176 are repeated until the predetermined D pressure control is completed. When the D pressure control ends, the process ends.

  In response to the transmission of the target range signal TR, the hydraulic pressure control means provided in step 175 and step 176 changes the D pressure in the D range, which is the target range, from the D pressure hydraulic state (open state) in the R range before switching. The pressure increase control to the hydraulic pressure state (pressurization state) is executed. The hydraulic pressure control means provided by step 175 and step 176 can be called D pressure control means. The D pressure control means controls the D pressure from the hydraulic pressure that provides the disengaged state to the hydraulic pressure that provides the engaged state. The D pressure control means is also a hydraulic pressure control means for executing the hydraulic pressure control based on the start time T2 planned in step 173, which is a planning means.

  FIG. 6 is a time chart showing changes in the state of AT2 in the PD range switching of the first embodiment, where (A) shows the change of the target range, (B) shows the change of the current range, (C ) Shows a change in R pressure, and (D) shows a change in D pressure. By operating the shift operation unit 31, the target range is switched from the P range to the D range at time T1. The range ECU 35 moves the manual lever 21 by controlling the motor 33. As a result, the current range changes in the order of P, PR, R, RN, N, ND, and D. After time T1, range ECU 35 transmits target range signal TR to transmission ECU 36. In the P-D switching, the R pressure control is not executed because it is not necessary to apply the R pressure. The speed change ECU 36 sets the time T2 based on the time TD (P-D) that the range ECU 35 is predicted to require for switching from the P range to the D range. Time T2 can be set as the time when time TD (P-D) has elapsed from time T2. AT2 reaches the D range almost at time T2 by the range switching control by the range ECU 35. When the time T2 elapses, the D pressure control is started. The D pressure control is started at time T2 without depending on the current range signal PR. In order for the range ECU 35 to output the current range signal PR, a predetermined determination time is required after reaching the D range for processing by the range ECU 35 and filter processing for suppressing erroneous determination due to noise. However, D pressure control is started without waiting for a fixed time.

  According to this embodiment, the hydraulic control executed by the hydraulic control means is executed based on the target range signal TR transmitted from the range ECU 35 to the transmission ECU 36 without depending on the range switching by the motor 33. For this reason, there is a case where the hydraulic control can be executed without waiting for the range switching by the motor 33. In some cases, hydraulic control can be executed without waiting for a fixed time required to detect the actual range. As a result, after range switching is requested, AT2 can be put in an operating state corresponding to the target range at an early stage.

  According to this embodiment, the hydraulic control executed by the hydraulic control means is planned by the planning means. Moreover, the planning means predicts the time when the range of AT2 is switched to the target range. Then, hydraulic control is planned based on the predicted time. Specifically, after the range switching of AT2 is requested, the time when the switching to the target range is completed by the range ECU 35 and the shift ECU 36 is predicted. As a result, the plan of the hydraulic control is set by predicting the progress of the range switching control provided by the range switching control device 35. Then, the transmission ECU 36 performs hydraulic control based on the set plan. Therefore, the hydraulic control is planned and executed without depending on the actual range of AT2 switched by the motor 33. For this reason, there is a case where the hydraulic control can be executed without waiting for the range switching by the actuator. In some cases, hydraulic control can be executed without waiting for a fixed time required to detect the actual range. As a result, after range switching is requested, AT2 can be put in an operating state corresponding to the target range at an early stage.

(Second Embodiment)
In the first embodiment, the shift ECU 36 performs R pressure control and D pressure control. In the second embodiment to which the present invention is applied, in addition to the hydraulic control in the first embodiment, line pressure control is further executed. Also in the second embodiment, the block configuration shown in FIG. 1 is adopted.

  FIG. 7 is a flowchart showing the RD shift control 260 according to the second embodiment. In FIG. 7, Steps 161-167 are the same as Steps 161-167 in the first embodiment. In the second embodiment, steps 261 to 264 are added.

  In step 261, line pressure control start time T3 is set. In the line pressure control, an increase in the D pressure is promoted by increasing the line pressure before the D pressure control is started. Thereby, the time required for D pressure control is shortened. As a result, the responsiveness of AT2 in range switching is further improved. The start time T3 is set as a time that is a predetermined time before the start time T2.

  Steps 163 and 261 provide planning means for planning control of the line pressure. The planning means predicts a time T2 when the range of AT2 is switched to the target range, and sets a time T3 for increasing the line pressure based on the predicted time T2.

  In step 262, it is determined whether the start time T3 has elapsed. When the start time T3 has elapsed, the process proceeds to step 263. In step 263, line pressure control is executed. In the line pressure control, the line pressure is increased to a predetermined pressure or by a predetermined pressure. In the line pressure control, the solenoid valve 24 is controlled so that the line pressure changes in a predetermined pattern for RD switching. In the line pressure control, a predetermined increase is generated in the line pressure before applying the D pressure. The line pressure control is started regardless of whether or not the AT2 range has reached the D range. The line pressure control is started before the current range reaches the D range. In step 264, it is determined whether the D pressure control is finished and the line pressure control is finished. The loop of steps 166, 167, 262, 263, 264 is repeated until both controls are finished. When both controls are finished, the process is finished.

  In response to the transmission of the target range signal TR, the hydraulic pressure control means provided by Step 263 and Step 264 changes the line pressure in the D range, which is the target range, from the hydraulic pressure state (low pressure state) in the R range before switching. The pressure increase control to the hydraulic pressure state (high pressure state) is executed. The hydraulic pressure control means provided by step 263 and step 264 can be called line pressure control means. The line pressure control means temporarily increases the line pressure in response to transmission of the target range signal TR. The line pressure control means is also a hydraulic pressure control means for executing the hydraulic pressure control based on the start time T3 planned in step 261 which is a planning means.

  FIG. 8 is a time chart showing changes in the state of AT2 in the RD range switching of the second embodiment, where (A) shows the change of the target range, (B) shows the change of the current range, (C ) Shows a change in R pressure, (D) shows a change in D pressure, and (E) shows a change in line pressure. The description of FIG. 4 can be referred to for (A)-(D). After setting the time T2, the speed change ECU 36 sets the time T3 based on the time TL required to increase the line pressure. Time T3 is a time before time TL by time TL. Thus, the line pressure control is executed without depending on the current range signal PR, that is, without waiting for completion of switching to the D range.

  FIG. 9 is a flowchart showing the PD shift control 270 of the second embodiment. In FIG. 9, steps 171-175 are the same as steps 171-175 in the first embodiment. In the second embodiment, steps 271 to 274 are added.

  In step 271, the line pressure control start time T3 is set. Steps 173 and 271 provide a planning means for planning the control of the line pressure. The planning means predicts a time T2 when the range of AT2 is switched to the target range, and sets a time T3 for increasing the line pressure based on the predicted time T2.

  In step 272, it is determined whether the start time T3 has elapsed. When the start time T3 has elapsed, the process proceeds to step 273. In step 273, line pressure control is executed. In the line pressure control, the line pressure is increased to a predetermined pressure or by a predetermined pressure. In step 274, it is determined whether the D pressure control is finished and the line pressure control is finished. The loop of steps 174, 175, 272, 273, 274 is repeated until both controls are finished. When both controls are finished, the process is finished.

  In response to the transmission of the target range signal TR, the hydraulic pressure control means provided in Step 273 and Step 274 changes the line pressure in the D range, which is the target range, from the hydraulic pressure state (low pressure state) in the R range before switching. The pressure increase control to the hydraulic pressure state (high pressure state) is executed. The hydraulic pressure control means provided by step 273 and step 274 can be called line pressure control means. The line pressure control means temporarily increases the line pressure in response to transmission of the target range signal TR. The line pressure control means is also a hydraulic pressure control means for executing the hydraulic pressure control based on the start time T3 planned in step 261 which is a planning means.

  FIG. 10 is a time chart showing changes in the state of AT2 in the PD range switching of the second embodiment, where (A) shows the change of the target range, (B) shows the change of the current range, (C ) Shows a change in R pressure, (D) shows a change in D pressure, and (E) shows a change in line pressure. The description of FIG. 6 can be referred to for (A) to (D). After setting the time T2, the speed change ECU 36 sets the time T3 based on the time TL required to increase the line pressure. Time T3 is a time before time TL by time TL. Thus, the line pressure control is executed without depending on the current range signal PR, that is, without waiting for completion of switching to the D range.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. The structure of the said embodiment is an illustration to the last, Comprising: The scope of the present invention is not limited to the range of these description. The scope of the present invention is indicated by the description of the scope of claims, and further includes meanings equivalent to the description of the scope of claims and all modifications within the scope.

  For example, the means and functions provided by the control device can be provided by software only, hardware only, or a combination thereof. For example, the control device may be configured by an analog circuit.

  In the above embodiment, the transmission ECU 36 sets the start times T2 and T3. Instead, at least one of the start times T2 and T3 may be set in the range ECU 35 and transmitted to the transmission ECU 36. The range ECU 35 is a control device that controls the motor 33. For this reason, the time when the range of AT2 reaches the target range may be accurately predicted. Further, in the setting process of the start times T2 and T3 in the range ECU 35 or the speed change ECU 36, the start times T2 and T3 may be corrected based on the power supply voltage and / or the temperature in consideration of the characteristic change of the motor 33.

1 Internal combustion engine 2 Automatic transmission (AT)
DESCRIPTION OF SYMBOLS 21 Manual lever 22 Solenoid valve 23 Solenoid valve 24 Solenoid valve 3 Control system 31 Shift operation part 32 Shift sensor 33 Motor 34 Encoder 35 Range switching control apparatus (range ECU)
36 Transmission control device (transmission ECU)

Claims (12)

A range switching control device (35) for switching the range of the automatic transmission by driving an actuator;
A shift control device (36) comprising hydraulic control means for controlling the hydraulic pressure of the automatic transmission according to the range;
Transmission means for transmitting at least a target range from the range switching control device to the shift control device before the range switching by the actuator is completed,
The automatic transmission, wherein the hydraulic control means controls the hydraulic pressure based on the target range transmitted from the range switching control device to the transmission control device without depending on the range switching by the actuator. Control device.   The hydraulic control means (164-165) executes control from a hydraulic state in a range before switching to a hydraulic state in the target range in response to transmission of the target range. A control device for an automatic transmission according to claim 1.   The automatic transmission according to claim 2, wherein the hydraulic pressure control means controls the hydraulic pressure that provides the engaged state to the hydraulic pressure that provides the disengaged state in response to transmission of the target range. Control device.   In the case of switching from the R range to the D range, the hydraulic pressure control means includes an R pressure control means (164-165) for reducing the R pressure in the R range before switching in response to transmission of the target range. The control device for an automatic transmission according to claim 3, further comprising:   The hydraulic pressure control means controls the hydraulic pressure that provides the disengaged state to the hydraulic pressure that provides the engaged state in response to transmission of the target range. A control device for an automatic transmission according to claim 1.   In the case of switching from the R range to the D range or from the P range to the D range, the hydraulic pressure control means increases the D pressure in the D range after switching in response to transmission of the target range. The control apparatus for an automatic transmission according to claim 5.   The hydraulic pressure control means further comprises line pressure control means (261-264, 271-274) for increasing the line pressure in response to transmission of the target range. A control device for an automatic transmission according to claim 1. Furthermore, it comprises a planning means (163, 173, 261, 271) for predicting the time (T2) at which the range of the automatic transmission is switched to the target range and planning the hydraulic pressure control based on the predicted time
The hydraulic control means (164-168, 174-176, 262-264, 272-274) is configured to control hydraulic pressure based on the plan. The control apparatus of the automatic transmission in any one. The planning means predicts a time (T2) when switching to the D range when switching from the R range to the D range or switching from the P range to the D range,
9. The control apparatus for an automatic transmission according to claim 8, wherein the hydraulic pressure control means increases the D pressure when the time elapses. The planning means sets a time (T3) for increasing the line pressure based on the time (T2) when the plan is switched to the D range,
The said hydraulic pressure control means (261-264, 271-274) further increases the line pressure when the time (T3) when the line pressure is increased passes. Control device for automatic transmission.   The control apparatus for an automatic transmission according to any one of claims 8 to 10, wherein the shift control apparatus includes the planning unit. The range switching control device includes the planning means,
11. The automatic transmission control device according to claim 8, wherein the transmission unit transmits the target range and the plan from the range switching control device to the shift control device. .

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