JP2011208680A - Continuously variable transmission and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the belt slip even when supply pressure to a pulley is in shortage during a coordinated shift in a continuously variable transmission which consists of a variator and an auxiliary transmission mechanism and executes the coordinated shift for changing a gear ratio of the variator in a direction opposite to a change direction of a gear ratio of the auxiliary transmission mechanism in accordance with the shift of the auxiliary transmission mechanism.SOLUTION: A transmission controller 12 operates a variator transmittable torque which is a transmittable torque of a variator 20 on the basis of supply pressure to a pulley and a gear ratio of the variator 20 and inertia torque inputted from an output side of the variator 20 on the basis of a rotation speed change in an output shaft of the variator 20 when supply pressure to the pulley is determined to be in shortage during the coordinated shift, and operates an upper limit torque of an engine 1 on the basis of the variator transmittable torque and inertia torque and regulates the torque of the engine 1 by outputting the operated upper limit torque to the engine controller.

Description

  The present invention relates to a continuously variable transmission having a belt-type continuously variable transmission mechanism and an auxiliary transmission mechanism, and more particularly to a technique for suppressing belt slip.

  When belt slip occurs in a belt type continuously variable transmission, it causes deterioration of the belt and pulley. Further, since the gear ratio deviates from the target gear ratio, it causes a reduction in drivability. For this reason, Patent Document 1 discloses a technique for converging belt slip while maintaining a target gear ratio by increasing supply pressure to a pulley and limiting engine torque when belt slip occurs. is doing.

  However, if the supply pressure to the pulley is reduced due to a failure of the hydraulic actuator, etc., the pulley supply pressure cannot be increased. There was a possibility that it could not be converged.

  Therefore, in general, when the supply pressure to the pulley is lower than the required pressure, the transmission is shifted to a gear ratio corresponding to the reduced supply pressure instead of increasing the supply pressure to the pulley. At the same time, the engine torque is regulated below the torque that can be transmitted by the transmission with the reduced supply pressure (hereinafter referred to as “general technology”). According to this technique, although the target gear ratio cannot be maintained, belt slip can be suppressed even in a situation where the supply pressure to the pulley cannot be increased.

Japanese Patent Laid-Open No. 2004-19777

  The applicant has been developing a continuously variable transmission in which a stepped transmission mechanism is provided on the output side of a belt-type continuously variable transmission mechanism (hereinafter referred to as “variator”). In such a continuously variable transmission, the speed ratio range achievable by the transmission can be expanded by shifting the auxiliary transmission mechanism. In addition, the through transmission ratio, which is the overall transmission ratio of the transmission, is reduced by performing a coordinated shift that changes the transmission ratio of the variator in the direction opposite to the change direction of the transmission ratio of the auxiliary transmission mechanism in accordance with the transmission of the auxiliary transmission mechanism. It can be kept constant or the change width can be reduced, and the uncomfortable feeling when the subtransmission mechanism shifts can be reduced.

  However, it has been found that when the above general technique is applied to such a continuously variable transmission as it is, belt slippage may not be suppressed if the supply pressure to the pulley is insufficient during coordinated shifting. This is because when the sub-transmission mechanism shifts (upshifts) to the small gear ratio side by cooperative shift, the inertia torque in the direction opposite to the engine torque is input from the output side of the variator, so that it is less than the torque that can be transmitted by the variator. This is because the sum of the engine torque and the inertia torque exceeds the torque that can be transmitted by the variator simply by regulating the engine torque.

  The present invention has been made in view of such a technical problem, and has a variator and a subtransmission mechanism, and the speed ratio of the variator is changed in accordance with the direction of change of the speed ratio of the subtransmission mechanism in accordance with the speed change of the subtransmission mechanism. An object of the present invention is to continuously suppress belt slippage even when a supply pressure to a pulley is insufficient during a coordinated shift in a continuously variable transmission that performs a coordinated shift to be changed.

  According to an aspect of the present invention, there is provided a variator that shifts rotation input from a power source by changing the groove width of the pulley by hydraulic pressure, and a plurality of forward shift stages provided on the output side of the variator. A continuously variable transmission that performs a coordinated shift that changes the speed ratio of the variator in a direction opposite to the direction of change of the speed ratio of the subtransmission mechanism during a shift of the subtransmission mechanism. A supply pressure shortage determining means for determining whether the supply pressure to the pulley is lower than a required pressure during the coordinated shift, and a variator transmittable torque, which is a torque that can be transmitted by the variator, to the supply pressure to the pulley. And a variator transmittable torque calculating means for calculating based on the variator gear ratio and an inertia torque input from the variator output side to rotate the output shaft of the variator An inertia torque calculating means for calculating based on a change in degree, and when it is determined that the supply pressure to the pulley is insufficient during the coordinated shift, the power source of the power source is determined based on the variator transmittable torque and the inertia torque. There is provided a continuously variable transmission, comprising: a torque regulating means for computing an upper limit torque and outputting the computed upper limit torque to a control device of the power source to regulate the torque of the power source. The

  According to another aspect of the present invention, a variator that shifts rotation input from a power source by changing the groove width of the pulley by hydraulic pressure, and a plurality of forward shift stages provided on the output side of the variator. And a sub-transmission mechanism having a sub-transmission mechanism, wherein the transmission ratio of the variator is changed to a direction opposite to the change direction of the sub-transmission mechanism during the shift of the sub-transmission mechanism. Performing the coordinated shift, and determining whether the supply pressure to the pulley is less than the required pressure during the coordinated shift, and determining that the supply pressure to the pulley is insufficient. Is calculated based on the supply pressure to the pulley and the transmission ratio of the variator, and an inertia torque inputted from the output side of the variator is calculated. Calculation based on a change in rotational speed of the force shaft, calculation of an upper limit torque of the power source based on the torque that can be transmitted by the variator and the inertia torque, and output the calculated upper limit torque to the control device of the power source There is provided a control method for a continuously variable transmission, comprising regulating torque of a power source.

  According to these aspects, when the supply pressure to the pulley becomes insufficient during the coordinated shift, the upper limit torque of the power source (for example, the engine) is calculated in consideration of the inertia torque, and the torque of the power source is regulated. . Thereby, even if the supply pressure to the pulley is insufficient during the coordinated shift, the belt slip can be suppressed.

1 is a schematic configuration diagram of a vehicle equipped with a continuously variable transmission according to an embodiment of the present invention. It is the figure which showed the internal structure of the transmission controller. It is the figure which showed an example of the transmission map. It is the flowchart which showed the content of the main routine of the shift control program performed by a transmission controller. It is an example of the map for calculating the variator transmittable torque. It is the flowchart which showed the content of the subroutine (cooperative shift control) of the shift control program performed by a transmission controller. It is a timing chart for demonstrating the effect of this invention. It is a timing chart for demonstrating the effect of this invention. It is a timing chart for demonstrating the effect of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following description, the “transmission ratio” of a transmission mechanism is a value obtained by dividing the input rotational speed of the transmission mechanism by the output rotational speed of the transmission mechanism. The “lowest speed ratio” is the maximum speed ratio of the transmission mechanism, and the “highest speed ratio” is the minimum speed ratio of the transmission mechanism.

  FIG. 1 is a schematic configuration diagram of a vehicle equipped with a continuously variable transmission according to an embodiment of the present invention. This vehicle includes an engine 1 as a power source. The output rotation of the engine 1 is via a torque converter 2 with a lock-up clutch, a first gear train 3, a continuously variable transmission (hereinafter simply referred to as "transmission 4"), a second gear train 5, and a final reduction gear 6. Is transmitted to the drive wheel 7. The second gear train 5 is provided with a parking mechanism 8 that mechanically locks the output shaft of the transmission 4 at the time of parking.

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

  The transmission 4 includes a belt-type continuously variable transmission mechanism (hereinafter referred to as “variator 20”) and an auxiliary transmission mechanism 30 provided in series with the variator 20. “Provided in series” means that the variator 20 and the auxiliary transmission mechanism 30 are provided in series in the power transmission path from the engine 1 to the drive wheels 7. The auxiliary transmission mechanism 30 may be directly connected to the output shaft of the variator 20 as in this example, or may be connected via another transmission or power transmission mechanism (for example, a gear train).

  The variator 20 includes a primary pulley 21, a secondary pulley 22, and a belt 23 that is wound around the pulleys 21 and 22. The belt 23 is configured by connecting a number of elements with an endless metal belt, but a chain belt may be used as the belt 23. Each of the pulleys 21 and 22 includes a fixed conical plate, a movable conical plate that is arranged with a sheave surface facing the fixed conical plate, and forms a V-groove between the fixed conical plate and the movable conical plate. The hydraulic cylinders 23a and 23b are provided on the back of the movable cylinder to displace the movable conical plate in the axial direction. When the hydraulic pressure supplied to the hydraulic cylinders 23a, 23b is adjusted, the width of the V-groove changes, the contact radius between the belt 23 and each pulley 21, 22 changes, and the transmission ratio of the variator 20 changes steplessly.

  The subtransmission mechanism 30 is a transmission mechanism having two forward speeds and one reverse speed. The sub-transmission mechanism 30 is connected to a Ravigneaux type planetary gear mechanism 31 in which two planetary gear carriers are connected, and a plurality of friction elements connected to a plurality of rotating elements constituting the Ravigneaux type planetary gear mechanism 31 to change their linkage state. Fastening elements (Low brake 32, High clutch 33, Rev brake 34) are provided. When the supply pressure to each of the frictional engagement elements 32 to 34 is adjusted and the engagement / release state of each of the frictional engagement elements 32 to 34 is changed, the gear position of the auxiliary transmission mechanism 30 is changed.

  For example, if the Low brake 32 is engaged and the High clutch 33 and the Rev brake 34 are released, the gear position of the subtransmission mechanism 30 is the first speed. If the high clutch 33 is engaged and the low brake 32 and the rev brake 34 are released, the speed stage of the subtransmission mechanism 30 becomes the second speed having a smaller speed ratio than the first speed. Further, if the Rev brake 34 is engaged and the Low brake 32 and the High clutch 33 are released, the shift speed of the subtransmission mechanism 30 is reverse. In the following description, the state where the gear position of the subtransmission mechanism 30 is the first speed is expressed as “the transmission 4 is in the low speed mode”, and the state where the second speed is the “the transmission 4 is in the high speed mode”. ".

  As shown in FIG. 2, the transmission controller 12 includes a CPU 121, a storage device 122 including a RAM and a ROM, an input interface 123, an output interface 124, and a bus 125 that interconnects them.

  The input interface 123 includes an output signal of an accelerator opening sensor 41 that detects an accelerator opening APO that is an operation amount of an accelerator pedal, an input rotation speed of the transmission 4 (= rotation speed of the primary pulley 21, hereinafter, “primary rotation”). The output signal of the primary rotational speed sensor 42 for detecting the speed Npri "), the output rotational speed of the variator 20 (= the secondary rotational speed of the secondary pulley 22, hereinafter referred to as" secondary rotational speed Nsec "). The output signal of the sensor 43, the secondary pressure sensor 44 for detecting the supply pressure to the secondary pulley 22 (hereinafter referred to as "actual secondary pressure Psec"), the output signal of the inhibitor switch 45 for detecting the position of the select lever, and the vehicle speed VSP. An output signal of the vehicle speed sensor 46 to be detected is input. .

  The storage device 122 stores a shift control program (FIGS. 4 and 6) for the transmission 4 and maps (FIGS. 3 and 5) used in the shift control program. The CPU 121 reads out and executes a shift control program stored in the storage device 122, performs various arithmetic processes on various signals input via the input interface 123, generates a shift control signal, and generates the generated shift control program. A control signal is output to the hydraulic control circuit 11 via the output interface 124. Various values used in the arithmetic processing by the CPU 121 and the arithmetic results are appropriately stored in the storage device 122.

  The hydraulic control circuit 11 includes a plurality of flow paths and a plurality of hydraulic control valves. Based on the shift control signal from the transmission controller 12, the hydraulic control circuit 11 controls a plurality of hydraulic control valves to switch the hydraulic pressure supply path, and prepares the necessary hydraulic pressure from the hydraulic pressure generated by the oil pump 10, Is supplied to each part of the transmission 4. As a result, the gear ratio of the variator 20 and the gear position of the subtransmission mechanism 30 are changed, and the transmission 4 is shifted.

  The transmission controller 12 obtains torque information of the engine 1 from an engine controller (not shown), and transmits the torque of the engine 1 without sliding the belt 23 based on the torque information and the actual gear ratio of the variator 20. The thrust of the pulleys 21 and 22 is calculated, and the primary required pressure and the secondary required pressure are calculated based on the calculated required thrust and the pressure receiving area of the pulleys 21 and 22. Also in the variator 20 of the present embodiment, the secondary pressure is responsible for holding the belt 23 without slipping against the torque input from the road surface, similarly to a general belt type continuously variable transmission, and the transmission ratio is set. The primary pressure plays the role of holding.

  The variator 20 is shifted by breaking the balance of the primary pressure with respect to the secondary pressure. Specifically, when shifting the variator 20, the stroke speed of the primary pulley 21 necessary for causing the gear ratio of the variator 20 to follow the target gear ratio is calculated, and is necessary for realizing this stroke speed. The differential thrust is calculated, and these necessary pressures are corrected based on this.

  Based on these necessary pressures, the transmission controller 12 calculates a target value of the line pressure that is the primary pressure of the primary pressure and the secondary pressure, and controls the hydraulic control circuit 11 so that the target line pressure is obtained.

  FIG. 3 shows an example of the shift map stored in the storage device 122. Based on this shift map, the transmission controller 12 controls the variator 20 and the subtransmission mechanism 30 according to the driving state of the vehicle (in this embodiment, the vehicle speed VSP, the primary rotational speed Npri, and the accelerator opening APO).

  In this shift map, the operating point of the transmission 4 is defined by the vehicle speed VSP and the primary rotational speed Npri. The slope of the line connecting the operating point of the transmission 4 and the zero point of the lower left corner of the transmission map is the transmission ratio of the transmission 4 (the overall transmission ratio obtained by multiplying the transmission ratio of the variator 20 by the transmission ratio of the subtransmission mechanism 30; , Referred to as “through gear ratio”). Similar to the shift map of the conventional belt type continuously variable transmission, a shift line is set for each accelerator opening APO, and the shift of the transmission 4 is selected according to the accelerator opening APO. According to the shift line. For simplicity, FIG. 3 shows a full load line (shift line when accelerator opening APO = 8/8), partial line (shift line when accelerator opening APO = 4/8), coast line ( Only the shift line when the accelerator opening APO = 0/8 is shown.

  When the transmission 4 is in the low speed mode, the transmission 4 can be obtained by setting the low speed mode Low line obtained by setting the transmission ratio of the variator 20 to the lowest transmission ratio, and the low speed mode obtained by setting the transmission ratio of the variator 20 to the highest transmission ratio. The speed can be changed between the highest lines. In this case, the operating point of the transmission 4 moves in the A region and the B region. On the other hand, when the transmission 4 is in the high speed mode, the transmission 4 can be obtained by setting the maximum speed line of the high speed mode obtained by setting the transmission ratio of the variator 20 as the lowest transmission ratio and the transmission ratio of the variator 20 as the highest transmission ratio. It is possible to shift between the high-speed mode highest line. In this case, the operating point of the transmission 4 moves in the B region and the C region.

  The gear ratio of each gear stage of the sub-transmission mechanism 30 is such that the gear ratio corresponding to the low speed mode highest line (low speed mode highest high gear ratio) corresponds to the high speed mode lowest line (high speed mode lowest gear ratio). It is set to be smaller than that. Accordingly, the range of the through speed ratio of the transmission 4 that can be achieved in the low speed mode (“low speed mode ratio range” in the figure) and the range of the through speed ratio of the transmission 4 that can be taken in the high speed mode (“high speed mode” in the figure). Ratio range ”) partially overlaps and the operating point of the transmission 4 is in the B region sandwiched between the high-speed mode lowest line and the low-speed mode highest line, the transmission 4 is in the low-speed mode and the high-speed mode. Either mode can be selected.

  Further, on this shift map, a mode switching shift line for shifting the subtransmission mechanism 30 is set so as to overlap the low speed mode highest line. The through speed change ratio (hereinafter referred to as “mode change speed change ratio mRatio”) corresponding to the mode change speed change line is set to a value equal to the low speed mode highest speed change ratio. The reason why the mode switching shift line is set in this way is that the smaller the gear ratio of the variator 20 is, the smaller the input torque to the subtransmission mechanism 30 is, so that a shift shock when shifting the subtransmission mechanism 30 can be suppressed. .

  When the operating point of the transmission 4 crosses the mode switching speed line, that is, the actual value of the through speed ratio (hereinafter referred to as “actual through speed ratio Ratio”) changes across the mode switching speed ratio mRatio. In this case, the transmission controller 12 performs the cooperative shift described below, and switches between the high speed mode and the low speed mode.

  In the coordinated shift, the transmission controller 12 shifts the auxiliary transmission mechanism 30 and changes the transmission ratio of the variator 20 in a direction opposite to the direction in which the transmission ratio of the auxiliary transmission mechanism 30 changes. At this time, the inertia phase in which the gear ratio of the auxiliary transmission mechanism 30 actually changes and the period in which the gear ratio of the variator 20 changes are synchronized. The change of the transmission ratio of the variator 20 in the direction opposite to the change of the transmission ratio of the auxiliary transmission mechanism 30 is to keep the actual through transmission ratio Ratio before and after the cooperative transmission, and there is a step in the actual through transmission ratio Ratio. This is to prevent the driver from feeling uncomfortable with the change in the input rotation caused by the occurrence.

  Specifically, when the actual through speed ratio Ratio of the transmission 4 changes the mode switching speed ratio mRatio from the Low side to the High side, the transmission controller 12 changes the speed of the subtransmission mechanism 30 to the first speed. The gear ratio of the variator 20 is changed to the Low side.

  Conversely, when the actual through speed ratio Ratio of the transmission 4 changes the mode switching speed ratio mRatio from the High side to the Low side, the transmission controller 12 changes the speed of the subtransmission mechanism 30 from the second speed to the first speed. The speed is changed (downshifted) and the gear ratio of the variator 20 is changed to High.

  In the present embodiment, the actual through speed ratio Ratio is kept constant before and after the cooperative shift, but the step of the actual through speed ratio Ratio may be reduced before and after the cooperative shift.

  Further, when the supply pressure to the secondary pulley 22 that plays a role of preventing the belt 23 from slipping with respect to the torque input from the road surface due to a failure of the oil pump 10 or the hydraulic control circuit 11 or the like, between the belt and the pulley The frictional force of the belt 23 is insufficient and the belt 23 slips, causing the pulleys 21 and 22 and the belt 23 to deteriorate. For this reason, when the supply pressure to the secondary pulley 22 is insufficient, the transmission controller 12 shifts the variator 20 to a speed ratio that can be realized with the reduced supply pressure, and the variator 20 is transmitted with the reduced supply pressure. The possible torque (hereinafter referred to as “variator transmission possible torque”) is calculated, and the upper limit torque of the engine 1 is calculated based on this. Then, the transmission controller 12 regulates the torque of the engine 1 by outputting the calculated upper limit torque to the engine controller (normal torque regulation).

  Further, when the subtransmission mechanism 30 shifts by the cooperative shift, an inertia torque associated with the shift of the subtransmission mechanism 30 is input from the output side of the variator 20 during the inertia phase. In particular, when the speed change direction of the subtransmission mechanism 30 is upshift, the inertia torque that accompanies the speed change acts in a direction opposite to the torque of the engine 1, so that the torque of the engine 1 can be transmitted to the variator by the normal torque regulation. There is a possibility that the belt 23 slips even if it is kept lower than the torque.

  Therefore, the transmission controller 12 calculates the upper limit torque of the engine 1 in consideration of the inertia torque when the supply pressure is insufficient during the coordinated shift, during the inertia phase, and based on this, calculates the upper limit torque of the engine 1. Regulate torque (Inner shuttle torque regulation). Further, before the inertia phase, the coordinated shift is interrupted so that the auxiliary transmission mechanism 30 does not enter the inertia phase, and the inertia torque that causes belt slip does not occur.

  FIG. 4 is a flowchart showing the contents of the main routine of the shift control program executed by the transmission controller 12. The shift control performed by the transmission controller 12 will be described in detail with reference to this.

  In S1, the transmission controller 12 retrieves values corresponding to the current vehicle speed VSP and the accelerator opening APO from the shift map shown in FIG. 3, and sets them as the reached primary rotational speed DsrREV. The reached primary rotational speed DsrREV is a primary rotational speed to be achieved at the current vehicle speed VSP and the accelerator opening APO, and is a steady target value of the primary rotational speed.

  In S2, the transmission controller 12 calculates the ultimate through speed ratio DRatio by dividing the ultimate primary rotational speed DsrREV by the vehicle speed VSP and the final reduction ratio fRatio of the final reduction gear 6. The reached through speed ratio DRatio is a through speed ratio to be achieved at the current vehicle speed VSP and the accelerator opening APO, and is a steady target value of the through speed ratio.

  In S3, the transmission controller 12 sets a target through speed ratio Ratio0 for changing the actual through speed ratio Ratio from a value at the time of start of shifting to the reached through speed ratio DRatio with a predetermined transient response. The target through speed ratio Ratio0 is a transient target value of the through speed ratio. The predetermined transient response is, for example, a first-order lag response, and the target through speed ratio Ratio0 is set so as to gradually approach the ultimate through speed ratio DRatio. Note that the actual through speed ratio Ratio is calculated as needed based on the current vehicle speed VSP and the primary rotational speed Npri.

  In S4, the transmission controller 12 controls the actual through speed ratio Ratio to the target through speed ratio Ratio0. Specifically, the transmission controller 12 calculates the target transmission ratio vRatio0 of the variator 20 by dividing the target through transmission ratio Ratio0 by the transmission ratio of the auxiliary transmission mechanism 30, and the actual transmission ratio vRatio of the variator 20 is the target transmission ratio vRatio0. The variator 20 is controlled so that As a result, the actual through speed ratio Ratio follows the reached through speed ratio DRatio with a predetermined transient response.

  In S5, the transmission controller 12 determines whether the supply pressure to the secondary pulley 22 is insufficient. The transmission controller 12 compares the actual secondary pressure Psec with the required secondary pressure, and determines that the supply pressure to the secondary pulley 22 is insufficient when the actual secondary pressure Psec is lower than the required secondary pressure. The reason why the supply pressure is insufficient based on the actual secondary pressure Psec is because the secondary pressure plays a role of holding the belt.

  Note that the method of determining that the supply pressure is insufficient is not limited to this method. For example, the determination may be made based on the line pressure that is the original pressure of the secondary pressure. Alternatively, the determination may be made based on a phenomenon caused by a shortage of supply pressure, for example, based on a difference between the actual speed ratio vRatio of the variator 20 and the target speed ratio vRatio0.

  If it is determined that the supply pressure to the secondary pulley 22 is insufficient, the process proceeds to S <b> 9 and torque regulation of the engine 1 is performed. If it is not determined that the supply pressure is insufficient, the process proceeds to S6.

  In S9, the transmission controller 12 refers to the map shown in FIG. 5 based on the secondary thrust obtained at the actual secondary pressure Psec and the actual transmission ratio vRatio of the variator 20, and the torque that can be transmitted by the variator 20 (hereinafter referred to as “variator transmission”). It is called “possible torque”). Then, the transmission controller 12 calculates the upper limit torque of the engine 1 based on the variator transmittable torque, outputs this to an engine controller (not shown), and restricts the torque of the engine 1 to the upper limit torque (normal torque restriction).

  In S6, the transmission controller 12 determines whether the operating point of the transmission 4 has crossed the mode switching speed line, that is, whether the actual through speed ratio Ratio has changed across the mode switching speed ratio mRatio. If a positive determination is made, the process proceeds to S8, and if a negative determination is made, the process proceeds to S7. In S8, the cooperative shift control shown in FIG. 6 is executed, which will be described later.

  In S7, the transmission controller 12 determines whether or not the shift of the transmission 4 has been completed. The transmission controller 12 determines that the shift is complete when the deviation between the actual through speed ratio Ratio and the reached through speed ratio DRatio becomes smaller than a predetermined value. If it is determined that the shift has been completed, the process ends. If not, the process returns to S3.

  FIG. 6 is a flowchart showing the contents of a subroutine (cooperative shift control) of the shift control program executed by the transmission controller 12. This subroutine is executed when the processing of FIG. 4 proceeds to S8. The coordinated shift control performed by the transmission controller 12 and the torque regulation performed when the supply pressure to the secondary pulley 22 is insufficient during the coordinated shift will be described in detail with reference to this.

  In S11, the transmission controller 12 starts cooperative shift. In the coordinated shift, the transmission controller 12 shifts the auxiliary transmission mechanism 30 and changes the actual transmission ratio vRatio of the variator 20 to a direction opposite to the direction in which the transmission ratio of the auxiliary transmission mechanism 30 changes. A step is not generated in the actual through speed ratio Ratio before and after.

  The speed change of the subtransmission mechanism 30 is performed through a preparation phase in which the engagement side frictional engagement element is precharged with hydraulic pressure, a torque via the engagement side frictional engagement element (a high clutch 33 for an upshift, and a low brake 32 for a downshift). Torque transmission until the transmission ratio change of the auxiliary transmission mechanism 30 is started, and the transmission ratio changes to the transmission ratio corresponding to the speed stage after the change after the change of the transmission ratio of the auxiliary transmission mechanism 30 is started. The process is completed through an inertia phase until it reaches, an end phase in which the hydraulic pressure of the engagement side frictional engagement element is increased to a value corresponding to the input torque, and the engagement side frictional engagement element is completely engaged. The four phases usually occur in this order, but in the upshift that occurs when the driver removes the accelerator pedal or the downshift that occurs when the driver depresses the accelerator pedal, the order of the torque phase and inertia phase is reversed. become.

  The transmission controller 12 performs the shift of the variator 20 in accordance with the inertia phase in which the transmission ratio of the auxiliary transmission mechanism 30 actually changes, and thereby maintains the actual through transmission ratio Ratio throughout the coordinated transmission.

  In S12, the transmission controller 12 determines whether the supply pressure to the secondary pulley 22 is insufficient. Whether the supply pressure is insufficient is determined by comparing the actual secondary pressure Psec and the required secondary pressure as in S5. If it is determined that the supply pressure is insufficient, the process proceeds to S14; otherwise, the process proceeds to S13.

  In S13, the transmission controller 12 determines whether the coordinated shift has been completed. The transmission controller 12 determines that the coordinated shift is completed when the hydraulic pressure increase for completely engaging the engagement-side frictional engagement element is completed in the end phase. If it is determined that the cooperative shift has been completed, the process ends. If not, the process returns to S3.

  In step S14 and subsequent steps that proceed after it is determined that the supply pressure is insufficient, torque regulation according to the shift state of the subtransmission mechanism 30 is executed.

  In S <b> 14, the transmission controller 12 determines the shift direction of the auxiliary transmission mechanism 30. If the shift direction is downshift, the process proceeds to S15, and if it is upshift, the process proceeds to S16.

  In S15, the transmission controller 12 performs the same normal torque regulation as in S9. That is, the transmission controller 12 calculates the upper limit torque of the engine 1 based on the variator transmittable torque without considering the inertia torque of the subtransmission mechanism 30 and outputs this to the engine controller to regulate the torque of the engine 1. To do. When the speed change direction of the subtransmission mechanism 30 is changed to the large speed ratio side by downshifting, the direction of the inertia torque inputted from the output side of the variator 20 becomes the same as the direction of the torque of the engine 1, so that the normal torque regulation Even so, slipping of the belt 23 can be suppressed.

  On the other hand, when the process proceeds to S16 because the shift direction is upshift, the transmission controller 12 determines which phase is the shift phase of the sub-transmission mechanism in S16 and S17. As a result of the determination, if the shift phase is the inertia phase, the process proceeds to S18. If the shift phase is before the inertia phase, the process proceeds to S19. If the shift phase is after the inertia phase, the process proceeds to S20.

  In S18, the transmission controller 12 performs inertia torque compatible torque regulation. When the shift direction of the subtransmission mechanism 30 is upshift and the shift phase is in the inertia phase, an inertia torque in the direction opposite to the torque of the engine 1 is input from the output side of the variator 20. Torque regulation can cause belt slippage. For this reason, the transmission controller 12 calculates an inertia torque inputted from the output side of the variator 20, and calculates the upper limit torque of the engine 1 based on a value obtained by subtracting the absolute value of the inertia torque from the variator transmittable torque. The inertia torque is calculated by calculating the angular acceleration of the output shaft of the variator 20 from the secondary rotational speed Nsec, and multiplying this by the inertia moment around the output shaft of the variator 20 that has been obtained in advance by calculation.

  The transmission controller 12 outputs the calculated upper limit torque to the engine controller and regulates the torque of the engine 1. Since the upper limit torque by the inertia torque compatible torque regulation is smaller than that at the normal torque regulation, the torque of the engine 1 can be suppressed by the inertia torque compatible torque regulation than by the normal torque regulation.

  In S19, the transmission controller 12 stops the cooperative shift and performs the same normal torque regulation as in S9. The reason why normal torque regulation is performed instead of inertia torque compatible torque regulation is that the inertia shift is not input to the variator 20 by stopping the coordinated shift before the inertia phase. It is because it can suppress.

  In S20, the transmission controller 12 performs the same normal torque regulation as in S9. The reason why normal torque regulation is performed instead of inertia torque compatible torque regulation is that the inertia phase has already ended when the process proceeds to S20, and belt slip can be suppressed even with normal torque regulation. .

  FIG. 7 shows a state in which cooperative shift is performed. The speed change ratio of the variator 20 is changed in accordance with the speed change phase of the subtransmission mechanism 30 in accordance with the inertia phase, so that the through speed change ratio is kept constant before and after the cooperative speed change. During the inertia phase, inertia torque is input from the output side of the variator 20 and the belt 23 becomes slippery. However, in this example, since the actual secondary pressure Psec is not lower than the secondary required pressure during shifting, belt slip occurs. Not.

  On the other hand, FIG. 8 shows an example in which the actual secondary pressure Psec is lower than the secondary required pressure when the shift phase of the auxiliary transmission mechanism 30 is the inertia phase during the coordinated shift. Since inertia torque is input from the output side of the variator 20 during the inertia phase, there is a possibility that the belt 23 slips under normal torque regulation. However, according to the above control, the inertia torque is also taken into account. The upper limit torque of the engine 1 is set, and based on this, the torque of the engine 1 is regulated (S18). That is, the torque of the engine 1 can be kept lower than that during normal torque regulation. As a result, the sum of the engine torque and inertia torque (absolute value) can be suppressed below the variator transmittable torque, and the belt 23 can be prevented from slipping.

  FIG. 9 shows an example in which a shortage of supply pressure occurs before the inertia phase. When the coordinated shift is continued and the inertia phase is shifted to, the inertia torque is input from the output side of the variator 20 and the belt 23 becomes slippery. However, according to the above control, in such a case, the coordinated shift is stopped, and the inertia torque that causes the belt slip does not occur. Since normal torque regulation is then performed, slipping of the belt 23 is effectively suppressed (S19).

  Then, the effect of the said embodiment is demonstrated.

  According to the above-described embodiment, when it is determined that the actual secondary pressure Psec is less than the required secondary pressure during the coordinated shift, the upper limit torque of the engine 1 is calculated based on the variator transmittable torque and the inertia torque. Based on this, the torque of the engine 1 is regulated. During the coordinated shift, the inertia torque associated with the shift is input from the output side of the variator 20 so that the belt 23 becomes slippery. However, the upper limit torque of the engine 1 is calculated in consideration of the inertia torque. 23 can be prevented from slipping (effect corresponding to claims 1 and 6).

  Such inertia torque compatible torque regulation is such that when the direction of the inertia torque input from the output side of the variator 20 is opposite to the direction of the torque of the engine 1, that is, the gear ratio of the subtransmission mechanism 30 changes to the smaller side. It is necessary when you do. In the above embodiment, the inertia phase compatible torque restriction is performed when the gear ratio of the subtransmission mechanism 30 changes to the small side. Therefore, the inertia phase compatible torque restriction is performed only in a situation required to suppress belt slip. Further, it is possible to suppress the deterioration of drivability due to the unnecessary torque regulation corresponding to inertia torque (effect corresponding to claim 2).

  In addition, the inertia torque acts on the variator 20 not only during the entire period of the coordinated shift, but only during the inertia phase in which the transmission ratio of the auxiliary transmission mechanism 30 actually changes. In the above embodiment, since the inertia phase compatible torque regulation is performed during the inertia phase, it is possible to suppress deterioration in drivability due to unnecessary inertia torque compatible torque regulation (effect corresponding to claim 3). .

  Even when the actual secondary pressure Psec is insufficient during the coordinated shift, the coordinated shift is interrupted and the inertia phase is not considered if the shift phase of the subtransmission mechanism 30 is before the inertia phase. Normal torque regulation is performed. As a result, the inertia torque itself that causes the belt slip does not occur, so that the slip of the belt 23 can be further suppressed, and the frequency of the inertia torque response torque regulation is reduced. Deterioration of drivability due to regulation can be suppressed (effect corresponding to claim 4).

  Further, when the gear ratio of the subtransmission mechanism 30 changes to the large side, the inertia torque input to the variator 20 is in the same direction as the torque of the engine 1, and the pulley thrust necessary for holding the belt is reduced. In such a case, normal torque regulation is performed instead of inertia phase compatible torque regulation. Accordingly, it is possible to prevent the inertia torque compatible torque regulation from being performed in a situation where the belt slip can be suppressed by the normal torque regulation, and to suppress the deterioration of the drivability (effect corresponding to claim 5).

  The embodiment of the present invention has been described above, but the above embodiment is merely one example of application of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. is not.

  For example, in the above-described embodiment, the auxiliary transmission mechanism 30 is a transmission mechanism having two speeds of first speed and second speed as the forward shift stage. However, the auxiliary transmission mechanism 30 has three or more speeds as the forward shift stage. A transmission mechanism having stages may be used.

  Moreover, although the engine 1 is provided as a power source, the power source is not limited to the engine 1 and may be, for example, a power source combining the engine 1 and a motor, or a power source including only a motor.

1 ... Engine (power source)
DESCRIPTION OF SYMBOLS 4 ... Continuously variable transmission 11 ... Hydraulic control circuit 12 ... Transmission controller 20 ... Variator 21 ... Primary pulley 22 ... Secondary pulley 23 ... Belt 30 ... Sub-transmission mechanism

Claims (6)

A variator that shifts the rotation input from the power source by changing the groove width of the pulley by hydraulic pressure, and a sub-transmission mechanism that is provided on the output side of the variator and has a plurality of forward shift stages, A continuously variable transmission that performs a coordinated shift in which a gear ratio of the variator is changed in a direction opposite to a change direction of the gear ratio of the sub-transmission mechanism during a shift of the sub-transmission mechanism;
Supply pressure shortage determining means for determining whether the supply pressure to the pulley is lower than the required pressure during the coordinated shift,
Variator transmittable torque calculating means for calculating a variator transmittable torque that is a transmittable torque of the variator based on a supply pressure to the pulley and a transmission ratio of the variator;
An inertia torque calculating means for calculating an inertia torque input from the output side of the variator based on a change in rotational speed of the output shaft of the variator;
When it is determined that the supply pressure to the pulley is insufficient during the coordinated shift, the upper limit torque of the power source is calculated based on the variator transmittable torque and the inertia torque, and the calculated upper limit torque is calculated. Torque regulating means for regulating the torque of the power source by outputting to the control device of the power source;
A continuously variable transmission comprising: The continuously variable transmission according to claim 1,
When the torque regulating means determines that the supply pressure to the pulley is insufficient during the coordinated shift, and the shift of the sub-transmission mechanism is a shift toward a direction in which the gear ratio decreases, Calculating the upper limit torque based on a value obtained by subtracting the absolute value of the inertia torque from a variator transmittable torque;
A continuously variable transmission. The continuously variable transmission according to claim 1,
The torque restricting means determines that the supply pressure to the pulley is insufficient during the coordinated shift, and the shift of the sub-transmission mechanism is a shift in a direction in which the gear ratio decreases, and the sub-shift The upper limit torque is calculated based on a value obtained by subtracting the absolute value of the inertia torque from the variator transmittable torque when the gear shift phase of the mechanism is in the inertia phase;
A continuously variable transmission. A continuously variable transmission according to any one of claims 1 to 3,
The torque restricting means determines that the supply pressure to the pulley is insufficient during the coordinated shift, and the shift of the sub-transmission mechanism is a shift in a direction in which the gear ratio decreases, and the sub-shift When the gear shift phase of the mechanism is before the inertia phase, the shift of the auxiliary transmission is stopped, and the upper limit torque is calculated based on the variator transmittable torque.
A continuously variable transmission. A continuously variable transmission according to any one of claims 1 to 4,
The torque regulating means determines that the supply pressure to the pulley is insufficient during the coordinated shift, and when the shift of the sub-transmission mechanism is a shift in a direction in which the gear ratio increases, Calculate the upper limit torque based on the variator transmittable torque,
A continuously variable transmission. A variator that shifts the rotation input from the power source by changing the groove width of the pulley by hydraulic pressure, and a sub-transmission mechanism that is provided on the output side of the variator and has a plurality of forward shift stages. A control method for a step transmission, comprising:
Performing a coordinated shift in which the gear ratio of the variator is changed to a direction opposite to the direction of change of the gear ratio of the sub-transmission mechanism during a shift of the sub-transmission mechanism;
During the coordinated shift, when it is determined whether the supply pressure to the pulley is less than the required pressure, and when it is determined that the supply pressure to the pulley is insufficient,
A variator transmittable torque, which is a transmittable torque of the variator, is calculated based on a supply pressure to the pulley and a speed ratio of the variator,
An inertia torque inputted from the output side of the variator is calculated based on a change in rotational speed of the output shaft of the variator,
Calculating an upper limit torque of the power source based on the variator transmittable torque and the inertia torque, and outputting the calculated upper limit torque to a control device of the power source to regulate the torque of the power source;
A control method for a continuously variable transmission.

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