JP2007064371A - Control device for continuously variable transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress generation of belt slippage and deterioration of fuel economy. <P>SOLUTION: An ECT_ECU executes a program including a step (S102) of setting a moderating coefficient K as K=α when rapid decline in narrow pressure is not allowed (No in S100); a step (S104) of setting the moderating coefficient K as K=β when rapid decline in narrow pressure is allowed (Yes in S100); and a step (S106) of calculating a final target value. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a control device for a continuously variable transmission including a pair of pulleys and an endless belt, and in particular, when the target value of the oil pressure of the pulley decreases, the decrease of the oil pressure is moderated with respect to the decrease of the target value. Regarding control.

  Conventionally, in a belt-type continuously variable transmission, the effective engagement diameter of an endless belt wound around a pulley is changed by changing the groove width of the pulley by hydraulic pressure, and the gear ratio is controlled. The pulley is controlled to have a desired groove width by controlling the hydraulic pressure supplied to the pulley so that it reaches a target value that is set according to the opening of the throttle valve and the state of the vehicle. Be changed. A technique in which when the target value suddenly decreases, the target value is corrected so that the change in the hydraulic pressure supplied to the pulley becomes gradual, and the hydraulic pressure supplied to the pulley is controlled so as to correspond to the corrected target value. Is known.

  For example, Japanese Patent Application Laid-Open No. 3-244863 (Patent Document 1) discloses that even when the accelerator pedal is once depressed and then suddenly returned to the original position, or when suddenly depressed again after that, Disclosed is a hydraulic control device that does not slip. The hydraulic control device includes a pair of variable pulleys around which a transmission belt is wound, and a hydraulic actuator for applying a narrow pressure to the transmission belt to the variable pulley. In the vehicle belt type continuously variable transmission for transmitting power via a transmission belt, the hydraulic control device calculates a target value according to at least an input torque of the belt type continuously variable transmission from a predetermined relationship. Calculation means and control pressure control means for driving the control pressure regulating valve so that the control pressure applied to the hydraulic actuator becomes a target value. The hydraulic control device has a target value sudden decrease determination unit that determines that the calculated target value has rapidly decreased, and a target value calculated by the target value sudden decrease determination unit when it is determined that the target value has rapidly decreased. Includes target value correcting means for correcting the target value so as to change more slowly than the calculated target value.

According to the hydraulic control device disclosed in this publication, when the target pressure decreases rapidly in relation to the throttle valve opening, it is determined by the target value rapid decrease determination means that the target value has decreased sharply, The correction target value is gradually decreased from the target value by the value correction means. Then, the line pressure is changed so that the corrected target value is obtained by the control pressure control means. As a result, the occurrence of an insufficient region in which the line pressure becomes lower than the target pressure is eliminated, and slippage of the transmission belt in a transient state is eliminated.
JP-A-3-244863

  However, it is desirable to reduce the oil pressure of the pulley promptly as the target value decreases. This is because if the oil pressure does not drop quickly, the hydraulic pump operating loss increases and fuel consumption may deteriorate. In particular, when the torque fluctuation input to the continuously variable transmission is small, belt slip is unlikely to occur even if the target value rapidly decreases. In the hydraulic control device disclosed in the above-mentioned publication, the target value is set with priority given to securing the torque transmission capacity of the belt regardless of the torque input to the continuously variable transmission, so that the hydraulic pressure quickly decreases. Without it, there is a problem that fuel consumption deteriorates.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a control device for a continuously variable transmission that suppresses occurrence of belt slip and deterioration of fuel consumption.

  A control device for a continuously variable transmission according to a first aspect of the present invention is mounted on a vehicle, changes the groove width of a pulley by hydraulic pressure, and changes the effective engagement diameter of an endless belt wound around the pulley. This is a control device for a belt-type continuously variable transmission that controls the ratio. The control device is configured to detect whether or not the torque input to the continuously variable transmission is in a substantially constant state, and to set a target value of the hydraulic pressure according to the traveling state of the vehicle. Setting means and control means for controlling the oil pressure so as to be the set target value are included. The control means includes a first smoothing control means for controlling the hydraulic pressure so as to decrease at a predetermined first change rate if the torque is not in a substantially constant state when the target value decreases. When the target value decreases, if the torque is in a substantially constant state, second smoothing control means for controlling the hydraulic pressure so as to decrease at a second rate of change that is steeper than the first rate of change. Including.

  According to the first invention, when the target value decreases (for example, when the amount of decrease in the target value is equal to or greater than a predetermined value), the first smoothing control unit is configured to reduce the input torque. If the state is not constant, control is performed so as to decrease at a predetermined first change rate (for example, a change rate at the time of control in which the hydraulic pressure is gradually reduced with respect to the target value). When the target value decreases, the second smoothing control means determines that the input torque is in a substantially constant state (for example, when there is no output request to the power source and after returning from the neutral control) ), The hydraulic pressure is controlled to decrease at a second change rate that is steeper than the first change rate (the absolute value of the time change rate is large). As a result, when the fluctuation of the torque input to the continuously variable transmission is large, the hydraulic pressure is controlled to decrease at the first rate of change so as to be more gradual than the decrease of the target value. For this reason, the oil pressure gradually decreases, and the torque transmission capacity of the belt can be ensured, so that the occurrence of belt slip can be suppressed. On the other hand, when the torque input to the continuously variable transmission is in a state where the constant fluctuation is small, the hydraulic pressure is quickly reduced by reducing the hydraulic pressure at a second rate of change that is steeper than the first rate of change. Can be made. Therefore, the operating loss of the hydraulic pump is reduced, and deterioration of fuel consumption can be suppressed. Further, since the fluctuation of the torque input to the continuously variable transmission is small, even if the hydraulic pressure decreases quickly, belt slip is unlikely to occur. Therefore, it is possible to provide a control device for a continuously variable transmission that can suppress occurrence of belt slip and deterioration of fuel consumption.

  In the control device for a continuously variable transmission according to the second invention, in addition to the configuration of the first invention, the detecting means detects a torque input to the continuously variable transmission from the power source of the vehicle. And means for detecting that the torque is in a substantially constant state when the detected amount of change in torque is equal to or less than a predetermined value.

  According to the second invention, the detecting means is a value in which the detected amount of change in torque (for example, the amount of change in the rotational speed of the power source corresponding to the input torque or the amount of change in the throttle opening) is predetermined. If it is below, it can be detected that the fluctuation of the input torque is small. Thereby, it is possible to detect whether or not the torque is in a substantially constant state.

  In the continuously variable transmission control apparatus according to the third aspect of the invention, in addition to the configuration of the first or second aspect, the first and second smoothing control means may be configured such that the target value is equal to or greater than a predetermined change amount. Means for controlling the oil pressure so that the oil pressure gradually decreases as the target value decreases.

  According to the third invention, the first and second smoothing control units control the hydraulic pressure to gradually decrease with respect to the decrease of the target value when the target value decreases by a predetermined change amount or more. . For example, when the target value suddenly decreases, the belt can be set by changing the rate of change according to the fluctuation of the torque input to the continuously variable transmission so that the hydraulic pressure gradually decreases with respect to the decrease in the target value. Slip generation and fuel consumption deterioration can be suppressed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

  With reference to FIG. 1, a power train of a vehicle including a control device according to the present embodiment will be described. The control apparatus according to the present embodiment is realized by ECT (Electronic Controlled Automatic Transmission) _ECU (Electronic Control Unit) 900 shown in FIG.

  As shown in FIG. 1, the power source 100 is connected to the speed change mechanism 200, and the output shaft 300 of the speed change mechanism 200 is connected to the left and right drive wheels 500 via the differential gear 400. Here, the power source 100 includes various power sources that can be used in the vehicle, such as an internal combustion engine such as a gasoline engine or a diesel engine, or an electric motor such as a motor, and a device that combines the internal combustion engine and the electric motor. In the following description, as a power source 100, fuel is directly injected into a cylinder, and a so-called direct injection gasoline engine capable of homogeneous combustion or stratified combustion is controlled by controlling the injection amount and timing, or the throttle opening is electrically An example in which a gasoline engine equipped with an electronic throttle valve that can be freely controlled will be described (hereinafter, the power source 100 will be referred to as the engine 100).

  The engine 100 is configured to be electrically controllable, and an engine ECU 800 mainly including a microcomputer for the control is provided. The engine ECU 800 is configured to control at least the output of the engine 100, and the output shaft rotational speed (engine rotational speed) NE and the requested output amount such as the accelerator opening PA are input as data for the control. Is done.

  This required output amount is a signal for increasing / decreasing the output of the engine 100, and the operation amount signal of the acceleration / deceleration operation device 700 such as an accelerator pedal operated by the driver and the operation amount are electrically processed. The obtained signal can be used, and in addition, it may be an output request amount signal from a cruise control system (not shown) for maintaining the vehicle speed at the set vehicle speed.

  The transmission mechanism 200 includes a fluid transmission mechanism 210, a forward / reverse switching mechanism 220, and a belt type continuously variable transmission (CVT) 230.

  The fluid transmission mechanism 210 is a device configured to transmit torque between an input-side member and an output-side member via a fluid such as oil, and is adopted as an example in a general vehicle. A torque converter can be mentioned. The fluid transmission mechanism 210 includes a lockup clutch 212. That is, the lock-up clutch 212 is a clutch configured to directly connect the input side member and the output side member by mechanical means such as a friction plate, and is an elastic body such as a coil spring for buffering. The damper 214 which consists of is provided.

  A hydraulic pump that is rotated by the engine 100 as a power source and has a discharge pressure that increases in accordance with the rotational speed is provided at a position close to the fluid transmission mechanism 210. Specifically, it is disposed between the fluid transmission mechanism 210 and the forward / reverse switching mechanism 220. When the fluid transmission mechanism 210 is provided in order to keep the engine 100 driven even when the vehicle is stopped, the automatic clutch that is automatically engaged and disengaged based on the state of the vehicle is The fluid transmission mechanism 210 can be used as a replacement.

  An input member of fluid transmission mechanism 210 is connected to an output member of engine 100, and an output member of fluid transmission mechanism 210 is connected to an input member of forward / reverse switching mechanism 220. This forward / reverse switching mechanism 220 is constituted by a double pinion type planetary gear mechanism as an example, and although not particularly shown, either one of the sun gear and the carrier is used as an input element and the other is used as an output element, and a ring gear is used. A brake element for selectively fixing, and a clutch element for integrating the entire planetary gear mechanism by selectively connecting any two rotating elements of the sun gear, the carrier, and the link gear. . That is, the forward state is set by engaging the clutch element, and the reverse state is set by engaging the brake element.

  A belt type continuously variable transmission 230 shown in FIG. 1 is a belt capable of continuously (continuously) changing the ratio of the rotation speed of the input side member and the rotation speed of the output side member, that is, the gear ratio. Type continuously variable transmission. An example of the belt type continuously variable transmission 230 will be described with reference to FIG.

  A driving pulley (also referred to as a primary pulley or an input pulley) 232, a driven pulley (also referred to as a secondary pulley or an output pulley) 234, and a belt 236 wound around these pulleys 232 and 234 are provided. . Each of the pulleys 232 and 234 includes a fixed sheave 238 and 240 and movable sheaves 242 and 244 that approach and separate from the fixed sheave 238 and 240. The movable sheaves 242 and 244 are fixed to the fixed sheaves 238 and 240. Are provided with hydraulic actuators 246 and 248 for pressing in the direction of approaching. These sheaves 238, 240, 242, and 244 form V-groove belt winding grooves (pulley grooves) 250 and 252 for winding the belt 236, respectively.

  A primary pulley 232 is attached to the input shaft 290, and a secondary pulley 234 is attached to the output shaft 300 disposed in parallel with the input shaft 290. The hydraulic chamber 256 inside the hydraulic actuator 248 in the secondary pulley 234 is supplied with hydraulic pressure corresponding to the required driving force determined based on the output request typified by the accelerator pedal opening PA, and the movable sheave 244 is fixed to the fixed sheave 240. By pressing the belt 236 to the side (by applying a narrow pressure to the belt 236), a tension necessary for transmitting torque is applied to the belt 236.

  In addition, hydraulic oil is supplied to and discharged from the hydraulic chamber 254 inside the hydraulic actuator 246 of the primary pulley 232 so that the speed ratio of the input shaft 290 matches the target input speed. That is, by changing the groove width (interval between the fixed sheaves 238 and 240 and the movable sheaves 242 and 244) in the pulleys 232 and 234, the wrapping radius (effective engagement diameter) of the belt 236 with respect to the pulleys 232 and 234 is changed. Shifting is executed by changing the size.

  More specifically, the shift is executed by feedback-controlling the hydraulic oil of the primary pulley 232 based on the rotational speed deviation (control deviation) between the actual input rotational speed and the target input rotational speed, and thus the control deviation is large. The faster the speed is changed.

  As shown in FIG. 3, the hydraulic control device of the continuously variable transmission 230 according to the present embodiment is configured to adjust the line pressure supplied to the hydraulic chambers 254 and 256 of the hydraulic actuators 246 and 248 by the hydraulic pump 912. A regulator valve 850 is included. The oil is sucked into the suction port 910 of the hydraulic pump 912 via the strainer 890, and the oil discharged from the discharge port 920 of the hydraulic pump 912 is supplied to the input port 940 of the primary regulator valve 850 through the oil passage 930. Is done. Note that an oil passage 1540 branched from a midway portion of the oil passage 930 is connected to an input port (none of which is shown) of the check valve. In the hydraulic circuits of FIGS. 2 and 3, “1” places mean that the oil passages are connected at places where “1” is given.

  The primary regulator valve 850 includes an input port 940 connected to the discharge port 920 of the hydraulic pump 912, a relief port 950 that communicates with the input port 940, and a spool 960 that connects or blocks the input port 940 and the relief port 950. A spring chamber 990 provided at one end of the spool 960, a pressure adjusting port 970 connected to the spring chamber 990 and receiving the hydraulic pressure adjusted by the linear solenoid valve 1070, A control port 980 provided on the end side and a spring 960A that is disposed in the spring chamber 990 and presses the spool 960 in a direction in which the input port 940 and the relief port 950 are blocked. The oil passage 930 is connected to the control port 980 through the orifice 982.

  The pressure relief valve 1100 is connected to the oil passage 1090. The pressure relief valve 1100 is supplied with a control pressure of a linear solenoid (SLS) 1070 from a port 1150. The spool 1130 slides up and down in FIG. 3 by the balance of the control pressure of the linear solenoid (SLS) 1070, the biasing force of the spring 1140, and the line pressure introduced from the port 1110. A spring 1140 is disposed in a control pressure chamber 1120 into which the control pressure of the linear solenoid (SLS) 1070 is introduced.

  When the force due to the line pressure exceeds the combined force of the control pressure of the linear solenoid (SLS) 1070 and the biasing force of the spring 1140, the spool 1130 moves downward in FIG. 3 and the oil passage 1090 and the drain port are connected via the port 1110. 1160 communicates. As a result, the hydraulic pressure is drained from the drain port 1160, and the line pressure is controlled.

  The linear solenoid (SLS) 1070 is introduced from the port 1060 with the hydraulic pressure controlled by the modulator valve (1) 1080 using the line pressure as the original pressure. The linear solenoid (SLS) 1070 generates a control pressure according to the current value determined by the duty signal transmitted from the ECT_ECU 900. A duty solenoid may be used instead of the linear solenoid (SLS) 1070.

  The hydraulic pressure of the hydraulic actuator 248 of the secondary pulley 234 is controlled by the modulator valve (2) 1040 so that the belt 236 does not slip. The modulator valve (2) 1040 is provided with a spool 1018 that can move in the axial direction and a spring 1016 that biases the spool 1018 in one direction.

  The oil passage 1010 branched from the middle of the oil passage 930 is introduced into the port 1012 of the modulator valve (2) 1040. A control pressure of a linear solenoid (SLS) 1070 is introduced into the port 1014 via an oil passage 1050. The spool 1018 slides up and down in FIG. 3 by the balance of the control pressure of the linear solenoid (SLS) 1070, the biasing force of the spring 1016, and the line pressure introduced into the port 1012. The spool 1018 slides up and down in FIG. 3 to communicate and block the port 1012 and the port 1030. That is, the output hydraulic pressure of the linear solenoid (SLS) 1070 is set as the pilot hydraulic pressure, the hydraulic pressure output from the port 1030 of the modulator valve (2) 1040 is adjusted, and the secondary pulley 234 connected from the port 1030 via the oil passage 1020. The hydraulic pressure in the hydraulic chamber 256 inside the hydraulic actuator 248 is regulated. Thereby, the narrow pressure of the belt 236 is increased or decreased.

  Here, the gear ratio of the continuously variable transmission 230 is the vehicle acceleration request (in other words, driving force request) determined from conditions such as vehicle speed and accelerator opening, and data stored in the ECT_ECU 900 (for example, engine rotation The engine 100 is controlled so as to be in an optimum state based on an optimum fuel consumption curve using the number and throttle opening as parameters.

  Specifically, the width of the groove 250 of the primary pulley 232 is adjusted by controlling the hydraulic pressure in the hydraulic chamber 254 of the hydraulic actuator 246 by a speed-up solenoid and a speed-down solenoid (both not shown). As a result, the winding radius of the belt 236 in the primary pulley 232 changes, and the ratio between the input rotation speed and the output rotation speed of the continuously variable transmission 230, that is, the gear ratio is controlled steplessly (continuously).

  Furthermore, by controlling the hydraulic pressure in the hydraulic chamber 256 of the hydraulic actuator 248, the width of the groove 252 of the secondary pulley 234 changes. That is, the clamping force (in other words, clamping force) in the axial direction of the secondary pulley 234 with respect to the belt 236 is controlled. The tension of the belt 236 is controlled by this clamping pressure, and the contact surface pressure between the primary pulley 232 and the secondary pulley 234 and the belt 236 is controlled. The hydraulic pressure in the hydraulic chamber 256 of the hydraulic actuator 248 is controlled based on the torque input to the continuously variable transmission 230, the gear ratio of the continuously variable transmission 230, and the like. The torque input to the continuously variable transmission 230 is determined based on the engine speed, the throttle opening, the torque ratio of the torque converter 70, and the like.

  In the belt-type continuously variable transmission 230, the speed ratio on the lowest speed side (maximum speed ratio: maximum speed ratio: with the belt 236 having a minimum radius of wrapping around the primary pulley 232 and the belt 236 having a maximum radius of wrapping around the secondary pulley 234 On the other hand, the belt 236 has a maximum wrapping radius with respect to the primary pulley 232 and a minimum wrapping radius with the belt 236 with respect to the secondary pulley 234. Ratio (minimum transmission ratio: maximum speed increase state) is set.

  Control of each state of engagement / release of the lockup clutch 212 in the transmission mechanism 200 and half-engagement with slipping, switching of the forward / reverse movement in the forward / reverse switching mechanism 220, and the transmission ratio of the belt-type continuously variable transmission 230 The control is basically performed based on the running state of the vehicle. For this control, an ECT_ECU 900 composed mainly of a microcomputer is provided.

  The ECT_ECU 900 is connected to the above-described engine ECU 800 so as to be able to perform data communication. On the other hand, as data for control, the ECT_ECU 900 is input to the vehicle speed, the input side rotational speed (input rotational speed NIN) and the output side rotational speed (output rotational speed) The number NOUT) is input. The rotation speed sensor 600 is a sensor that detects the rotation speed of the primary pulley 232, the secondary pulley 234, and the like in order to execute the shift control in the belt-type continuously variable transmission 230. The pulse gear teeth (not shown) pass through each other to generate a pulse signal in the electromagnetic pickup, and the above-mentioned input rotation speed NIN and output rotation speed NOUT are obtained on the basis of the interval and pulse width of the pulse signal. Configured as follows.

  The transmission mechanism 200 is automatically set in accordance with the stopped state (parking position: P position), reverse state (reverse position: R position), neutral state (neutral position: N position), and the running state of the vehicle. An automatic forward state in which normal travel is performed (drive position: D position), a state in which the pumping loss of the engine 100 is used as a braking force (brake position: B position), and a state in which the setting of a high-speed side gear ratio exceeding a predetermined value is prohibited A shift device 1000 for selecting each state (position) of (SD position) is provided, and this shift device 1000 is electrically connected to the ECT_ECU 900.

  For the belt-type continuously variable transmission 230 having the above-described configuration, the ECT_ECU 900 determines the target value (specifically, the narrow pressure of the secondary pulley 234 in accordance with the traveling state of the vehicle such as the vehicle speed and the accelerator pedal opening degree. Is set to the target value of the hydraulic pressure in the hydraulic chamber 256). The ECT_ECU 900 controls the hydraulic pressure in the hydraulic chamber 256 by outputting a control command to the linear solenoid (SLS) 1070 so that the hydraulic pressure of the secondary pulley 234 becomes a set target value.

  Further, when the accelerator pedal is suddenly released and the target value of the hydraulic pressure in the secondary pulley 234 decreases rapidly, the ECT_ECU 900 causes the hydraulic pressure in the hydraulic chamber 256 to gradually decrease with respect to the decrease in the target value. Control. Specifically, the ECT_ECU 900 corrects the target value so that the change in oil pressure becomes gentle, and controls (smoothing control) the oil pressure in the hydraulic chamber 256 so as to follow the corrected target value. In this way, since the hydraulic pressure (narrow pressure) can be prevented from suddenly decreasing, the torque transmission capacity of the belt 236 can be ensured and the occurrence of belt slip can be suppressed. In the present embodiment, as described above, ECT_ECU 900 performs control so that the hydraulic pressure gradually decreases with respect to the decrease in target value, for example, final target value POPTTGT (I) = previous final target value POPTTGT ( I-1) + smoothing coefficient K × (target value POPTT−previous final target value POPTTGT (I−1)) The final target value POPTTGT (I) is calculated every predetermined time and calculated. A control command is output to the linear solenoid (SLS) 1070 so that the final target value is obtained. The final target value is a corrected target value. In addition, I is a natural number, and an initial value is substituted for POPTTGT (0). Furthermore, the correction of the target value is not particularly limited to the above formula. The annealing coefficient K indicates the rate of change when the final target value changes from the previous final target value to match the target value every calculation cycle. The smaller the rate of change, the smaller the increment / decrement for each calculation cycle, and the final target value changes more slowly to match the target value than when the rate of change is large. Therefore, the hydraulic pressure is controlled so as to gradually become the target value.

  However, it is desirable that the hydraulic pressure in the hydraulic chamber 256 is quickly reduced as the target value decreases. This is because if the oil pressure does not decrease quickly, the operating loss of the hydraulic pump 912 increases, and the fuel consumption may deteriorate. In particular, in a state where the torque fluctuation input to the continuously variable transmission 230 is small, even if the target value decreases rapidly, belt slip is unlikely to occur.

  Therefore, according to the present invention, when the target value described above decreases, the ECT_ECU 900 reduces the hydraulic pressure at a predetermined change rate α unless the torque input to the continuously variable transmission 230 is in a substantially constant state. The hydraulic pressure is controlled so that when the input torque is in a substantially constant state, the hydraulic pressure is controlled so that the hydraulic pressure decreases at a change rate β that is steeper than the change rate α.

  Specifically, ECT_ECU 900 detects whether or not the torque input to continuously variable transmission 230 is in a substantially constant state. Here, “a state in which the torque is substantially constant” refers to a state in which a fluctuation in torque input from the engine 100 to the continuously variable transmission 230 is small. For example, ECT_ECU 900 calculates the amount of change in torque input to continuously variable transmission 230 during a predetermined period based on the rotational speed of engine 100, the throttle opening, and the torque ratio in fluid transmission mechanism 210. It should be noted that the relationship between at least one of engine speed, throttle opening, and torque ratio and torque may be stored in advance as a map. Further, the amount of change in torque may be an estimated value. The rotational speed of the engine 100 may be detected by a crank position sensor (not shown), the throttle opening may be detected by a throttle position sensor (not shown), and the torque ratio is determined by the fluid transmission mechanism. What is necessary is just to calculate using the map etc. which were previously memorize | stored in the input shaft rotational speed in 210, output shaft rotational speed, and memory. Here, the “change amount” is, for example, the difference between the maximum value and the minimum value of the torque calculated in a predetermined period before the target value described above decreases.

  The ECT_ECU 900 detects that the torque input to the continuously variable transmission 230 is in a substantially constant state when the calculated torque change amount is equal to or less than a predetermined value. The ECT_ECU 900 detects that the torque is in a substantially constant state when a state where the torque input to the continuously variable transmission 230 is equal to or less than a predetermined value continues for a predetermined period. Also good.

  Then, ECT_ECU 900 determines that the target value rapidly decreases when the target value of the narrow pressure of secondary pulley 234 at a predetermined time is decreased by a predetermined amount or more. Note that the predetermined time is not particularly limited.

  The ECT_ECU 900 sets the smoothing coefficient K as K = α if the torque is not in a substantially constant state when the target value decreases rapidly. The ECT_ECU 900 sets the smoothing coefficient K as K = β if the torque is in a substantially constant state when the target value decreases rapidly. The ECT_ECU 900 corrects the target value of the hydraulic pressure from the set smoothing coefficient K and the above formula. The ECT_ECU 900 controls the control value output to the linear solenoid (SLS) 1070 so that the corrected target value is obtained. Α and β are stored in advance in a memory as a table or the like.

  Hereinafter, with reference to FIG. 4, a control structure of a program executed by ECT_ECU 900 that is the control device for continuously variable transmission according to the present embodiment will be described.

  In step (hereinafter, step is described as S) 100, ECT_ECU 900 determines whether or not a rapid decrease in narrow pressure is permitted. Specifically, as described above, ECT_ECU 900 detects whether or not the torque input to continuously variable transmission 230 is in a substantially constant state, and detects that the torque is in a substantially constant state. It is determined that a rapid decrease in the narrow pressure is permitted. If the rapid decrease in the narrow pressure is permitted (YES in S100), the process proceeds to S104. If not (NO in S100), the process proceeds to S102.

  In S102, ECT_ECU 900 sets smoothing coefficient K as K = α. α is a predetermined value, and is not particularly limited as long as it is a value that can ensure a hydraulic pressure that does not cause belt slipping even if the input torque varies greatly. In S104, ECT_ECU 900 sets smoothing coefficient K as K = β. β is a value where the change in hydraulic pressure is steeper than α, that is, the absolute value of the time change rate is large, and a value that can ensure a hydraulic pressure at which belt fluctuation does not occur when the input torque fluctuation is substantially constant. If it is, it will not specifically limit. Note that β may have a different value depending on the input torque. That is, when the input torque is substantially constant and the input torque is low, the value may be a steeper value, and when the input torque is high, the value may be a gentler value.

  In S106, ECT_ECU 900 calculates final target value POPTTGT (I) based on the set smoothing coefficient K. The ECT_ECU 900 calculates the final target value POPTTGT (I) every calculation cycle, and outputs a control command to the linear solenoid (SLS) 1070 so as to be the calculated final target value.

  The operation of ECT_ECU 900, which is a control device for continuously variable transmission according to the present embodiment, based on the above-described structure and flowchart will be described with reference to FIG.

  As shown in FIG. 5A, at time T (0), the target value increases from P (0) to P (1) due to a request based on the state of the vehicle. Thereafter, at time T (1), the target value decreases from P (1) to P (0) according to the state of the vehicle. At this time, as shown in FIG. 5 (B), for example, the engine 100 is in an idling state, and a predetermined period before time T (1) (from T ′ (1) to T (1) If the amount of change in torque based on the engine speed, throttle opening, and torque ratio is equal to or less than a predetermined value during the period of time, the torque input to the continuously variable transmission 230 is substantially constant. As described above, a rapid decrease in the narrow pressure is permitted (YES in S100). At this time, the smoothing coefficient K is set as K = β (S104).

  The target value that changes in a step shape indicated by the solid line between T (1) and T (2) in FIG. 5A is corrected to the final target value indicated by the broken line in FIG. (S106). Then, a control command is output to the linear solenoid (SLS) 1070 so that the narrow pressure becomes the final target value.

  On the other hand, as shown in FIG. 5B, after time T (2), the torque input to continuously variable transmission 230 is changed from TQ (0) to TQ (1) in response to a request based on the state of the vehicle again. At the same time, the target belt value increases from P (0) to P (1) at time T (3). Thereafter, at time T (4), the target belt value decreases from P (1) to P (0). At this time, the amount of change in torque based on the engine speed in a predetermined period (period T ′ (4) to T (4)) before time T (4) is greater than a predetermined value. If it is larger, the torque input to continuously variable transmission 230 is not in a substantially constant state, and a sudden decrease in narrow pressure is not permitted (NO in S100). At this time, the smoothing coefficient K is set as K = α (S102).

  The target value that changes in a step shape indicated by the solid line after T (4) in FIG. 5A is corrected to the final target value indicated by the broken line in FIG. 5A by the above-described equation (S106). . Then, a control command is output to the linear solenoid (SLS) 1070 so that the hydraulic pressure in the hydraulic chamber 256 becomes the final target value.

  The change in the final target value indicated by the broken line between T (1) and T (3) in FIG. 5A is steeper than the change in the final target value indicated by the broken line after T (4) in FIG. Changes. Therefore, the hydraulic pressure in the hydraulic chamber 256 is controlled so as to quickly decrease.

  Further, in the present embodiment, as an example of the state of the vehicle in which the target hydraulic pressure value increases and decreases while the torque input to the continuously variable transmission 230 is substantially constant, the state of the vehicle at the time of return from neutral control Is mentioned.

  Hereinafter, with reference to FIG. 6, an explanation will be given of the control operation for gradually decreasing the hydraulic pressure with respect to the decrease in the target value when the ECT_ECU 900 that is the control device for the continuously variable transmission according to the present embodiment returns to the neutral control. To do.

  When the ECT_ECU 900 satisfies a predetermined condition while the vehicle is stopped, the ECT_ECU 900 executes neutral control. Specifically, when the ECT_ECU 900 detects that the D position is selected in the shift device 1000, the vehicle speed is substantially zero, and the brake pedal is depressed, The speed change mechanism 200 is controlled so that the clutch element in the forward / reverse switching mechanism 220 is in a half-engaged state. The predetermined condition is not particularly limited to detecting the above three states.

  Then, after the neutral control is executed, when the condition for returning from the neutral control is satisfied, for example, by stopping the depression of the brake pedal at time T (5), the clutch element in the transmission mechanism 200 is half-engaged. The speed change mechanism 200 is controlled so as to change from the state to the engaged state. At this time, since the clutch element is engaged, the torque fluctuates in the speed change mechanism 200, so that the target value is set to increase. At time T (6), when the clutch element is engaged and returns from the neutral control, the target value decreases rapidly unless the driver depresses the accelerator pedal and the output of the engine 100 is required. To do. At this time, if the amount of change in torque in a predetermined period (period from T ′ (6) to T (6)) before time T (6) is equal to or less than a predetermined value, the continuously variable transmission Assuming that the torque input to machine 230 is in a substantially constant state, a rapid decrease in the narrow pressure is permitted (YES in S100). At this time, the smoothing coefficient K is set as K = β (S104).

  The hydraulic pressure indicated by the solid line after T (6) in FIG. 6A is based on the change in the final target value when K = α, as indicated by the broken line after T (6) in FIG. Therefore, the hydraulic pressure in the hydraulic chamber 256 quickly decreases.

  As described above, according to the control device for a continuously variable transmission according to the present embodiment, when the fluctuation of the torque input to the continuously variable transmission is large, the change is made more gradual than the decrease of the target value. The hydraulic pressure is controlled to decrease at a rate α. For this reason, the oil pressure gradually decreases, and the torque transmission capacity of the belt can be ensured, so that the occurrence of belt slip can be suppressed. On the other hand, when the torque input to the continuously variable transmission is in a state where the constant fluctuation is small, the hydraulic pressure can be quickly reduced by decreasing the hydraulic pressure at a change rate β that is steeper than the change rate α. . Therefore, the operating loss of the hydraulic pump is reduced, and deterioration of fuel consumption can be suppressed. Further, since the fluctuation of the torque input to the continuously variable transmission is small, even if the hydraulic pressure decreases quickly, belt slip is unlikely to occur. Therefore, it is possible to provide a control device for a continuously variable transmission that can suppress occurrence of belt slip and deterioration of fuel consumption.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is a control block diagram of the automatic transmission according to the embodiment of the present invention. FIG. 2 is a detailed view of the CVT shown in FIG. 1. It is a figure which shows a part of hydraulic circuit for the transmission control of CVT. It is a flowchart which shows the control structure of the program performed with ECT_ECU which is a control apparatus of the continuously variable transmission which concerns on embodiment of this invention. It is a timing chart (the 1) which shows operation | movement of ECT_ECU which is a control apparatus of the continuously variable transmission which concerns on embodiment of this invention. It is a timing chart (the 2) which shows operation | movement of ECT_ECU which is a control apparatus of continuously variable transmission which concerns on embodiment of this invention.

Explanation of symbols

  100 engine, 200 transmission mechanism, 210 fluid transmission mechanism, 212 lock-up clutch, 214 damper, 220 forward / reverse switching mechanism, 230 continuously variable transmission, 232 primary pulley, 234 secondary pulley, 236 belt, 290 input shaft, 300 output shaft , 400 differential gear, 500 drive wheel, 600 rotation speed sensor, 700 acceleration / deceleration operation device, 800 engine ECU, 850 primary regulator valve, 900 ECT_ECU, 912 oil pump, 1000 shift device, 1040, 1080 modulator valve, 1070 linear solenoid, 1100 Pressure relief valve.

Claims (3)

A control device for a belt-type continuously variable transmission that is mounted on a vehicle and that changes the groove width of the pulley by hydraulic pressure and changes the effective engagement diameter of the endless belt wound around the pulley, thereby controlling the gear ratio. Because
Detecting means for detecting whether or not the torque input to the continuously variable transmission is in a substantially constant state;
A setting means for setting a target value of the hydraulic pressure according to a traveling state of the vehicle;
Control means for controlling the oil pressure so as to be the set target value,
The control means includes
A first smoothing control means for controlling the hydraulic pressure so as to decrease at a predetermined first change rate if the torque is not substantially constant when the target value decreases;
When the target value decreases, if the torque is in a substantially constant state, a second value for controlling the hydraulic pressure so as to decrease at a second rate of change that is steeper than the first rate of change. A control device for a continuously variable transmission, including an annealing control means. The detection means includes
Means for detecting torque input to the continuously variable transmission from a power source of the vehicle;
The control of the continuously variable transmission according to claim 1, further comprising means for detecting that the torque is in a substantially constant state when the detected change amount of the torque is equal to or less than a predetermined value. apparatus.   The first and second smoothing control means are means for controlling the hydraulic pressure to gradually decrease with respect to a decrease in the target value when the target value decreases by a predetermined change amount or more. The control device for a continuously variable transmission according to claim 1, comprising:

Images