surplus pressure is obtained from a difference between a hydraulic pressure value detected by a hydraulic pressure sensor and a target supplied hydraulic pressure. A determination is made about whether or not a possible hydraulic pressure in a prescribed time will become lower than a minimum required hydraulic pressure based on a current surplus pressure and a changing rate of the surplus pressure. If the possible hydraulic pressure is lower than the minimum required hydraulic pressure, correction is conducted to increase supplied hydraulic pressure. Accordingly, control is conducted so that the regularly required surplus pressure can be reduced to a minimum required amount.
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7. A computer-implemented method for controlling a belt-type continuously variable transmission which transmits an engine output to wheels by changing gears in a nonstep manner, the method comprising:
obtaining a target gear change ratio and a target gear change ratio changing rate based on a vehicle speed and acceleration instruction information;
obtaining a driven pulley required axial thrust required for motive power transmission in response to a transmission input torque and the gear change ratio without causing a belt slip;
setting the driven pulley required axial thrust as a driven pulley target axial thrust;
setting an axial thrust required by a driven pulley for changing the gear change ratio to the target gear change ratio at the target gear change ratio changing rate by use of the driven pulley target axial thrust as a driving pulley target axial thrust;
conducting speed change control by controlling an actuation hydraulic pressure based on target supplied hydraulic pressure set in response to the driven pulley target axial thrust and the driving pulley target axial thrust;
predicting a hydraulic pressure decreasing amount likely to occur in a prescribed time at a current hydraulic pressure changing rate based on a hydraulic pressure value of the actuation hydraulic pressure detected by a hydraulic pressure sensor;
predicting an actuation hydraulic pressure likely to occur in the prescribed time based on the predicted hydraulic pressure decreasing amount, and
correcting supplied hydraulic pressure to be increased if the predicted actuation hydraulic pressure is lower than a minimum required hydraulic pressure that is a predetermined surplus pressure for the actuation hydraulic pressure.
1. A control system for a belt-type continuously variable transmission which transmits an engine output to wheels by changing gears in a nonstep manner, the control system adapted to obtain a target gear change ratio and a target gear change ratio changing rate based on a vehicle speed and acceleration instruction information, obtain a driven pulley required axial thrust required for motive power transmission in response to a transmission input torque and a gear change ratio without causing a belt slip, set the driven pulley required axial thrust as a driven pulley target axial thrust, set an axial thrust required by a driven pulley for changing the gear change ratio to the target gear change ratio at the target gear change ratio changing rate by use of the driven pulley target axial thrust as a driving pulley target axial thrust, and conduct speed change control by controlling an actuation hydraulic pressure based on target supplied hydraulic pressure set in response to the driven pulley target axial thrust and the driving pulley target axial thrust,
the control system comprising a correction section adapted to predict a hydraulic pressure decreasing amount likely to occur in a prescribed time at a current hydraulic pressure changing rate based on a hydraulic pressure value of the actuation hydraulic pressure detected by a hydraulic pressure sensor, predict an actuation hydraulic pressure likely to occur in the prescribed time based on the predicted hydraulic pressure decreasing amount, and conduct a correction to increase supplied hydraulic pressure if the predicted actuation hydraulic pressure is lower than a minimum required hydraulic pressure that is a predetermined surplus pressure for the actuation hydraulic pressure.
2. The control system for a belt-type continuously variable transmission according to
3. The control system for a belt-type continuously variable transmission according to
4. The control system for a belt-type continuously variable transmission according to
5. The control system for a belt-type continuously variable transmission according to
6. The control system for a belt-type continuously variable transmission according to
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The present invention relates to a control system for a belt-type continuously variable transmission, particularly to achievement of appropriate control of surplus lateral pressure to a belt (clamp pressure) in the belt-type continuously variable transmission.
A belt-type continuously variable transmission has been known and used which includes a driving pulley in which a pulley width is adjustable, a driven pulley in which a pulley width is adjustable, and a belt member wound around between the driving pulley and the driven pulley. The transmission has a driving-side hydraulic actuator for controlling the pulley width (axial thrust control) of the driving pulley and a driven-side hydraulic actuator for controlling the pulley width (axial thrust control) of the driven pulley. By providing hydraulic pressure to both the hydraulic actuators, axial thrusts of both the pulleys are controlled to adjust settings of the pulley widths, thereby variably setting a gear change ratio in a nonstep manner.
In a control system for such a kind of belt-type continuously variable transmission, to prevent belt slip, the hydraulic pressure (axial thrust) acting on the driven pulley is controlled to apply a minimum required pulley axial thrust (belt clamping force). The balance between the pulley axial thrusts to adjust the change gear ratio is set by controlling the hydraulic pressure (axial thrust) acting on the driving pulley. In such a case, the axial thrust of the driven pulley is determined with a belt-transmitted torque (torque transmitted between the pulleys) and the gear change ratio. A pulley axial thrust ratio between the driving pulley and the driven pulley is obtained from a target gear change ratio and a transmitted torque ratio. A pulley axial thrust deviation is obtained from dynamic speed change characteristics and a feedback element of the gear change ratio. Consequently, the driving-side axial thrust (hydraulic pressure) is set to the value composed of the sum of the product of the driving-side pulley axial thrust and the pulley axial thrust ratio and the pulley axial thrust deviation.
Japanese Patent Application Publication No. 2000-18347 (Patent Document 1) discloses that a target speed change can be achieved while preventing a belt slip by use of the minimum required pulley axial thrust even in such a speed change that the axial thrust of the driving pulley largely decreases.
Japanese Patent Application Publication No. Hei 5-79550 (Patent Document 2) discloses that control is performed in response to pulsation of hydraulic pressure.
In a belt-type continuously variable transmission (CVT), it is required to output hydraulic pressure not lower than the minimum required pressure as a lateral pressure to the belt (clamp pressure) to prevent belt slip. Accordingly, it was required to set a surplus pressure in consideration of factors lowering hydraulic pressure such as pulsation, environmental change, aging degradation, product variability (variability among individual CVT products), and the like. Although a technology has been developed such that a hydraulic pressure sensor is used to detect decrease in hydraulic pressure due to environmental change or aging degradation to regularly keep a surplus pressure low, a certain amount of surplus pressure must be secured to cope with instantaneous decrease in hydraulic pressure or occurrence of pulsation. However, securing a surplus pressure may result in decreased fuel efficiency and further in decreased durability of the belt; therefore it is desired to improve such a situation.
The present invention has been made in consideration of such an above-described situation, an object is to provide a control system for a belt-type continuously variable transmission that allows control such that a regularly required surplus pressure can be reduced to a minimum required amount.
The present invention provides a control system (50) for a belt-type continuously variable transmission which transmits an engine output to wheels by changing gears in a nonstep manner, the control system adapted to obtain a target gear change ratio (itgt) and a target gear change ratio changing rate (ditgt) based on a vehicle speed and acceleration instruction information, obtain a driven pulley required axial thrust (Qdnnec) required for motive power transmission in response to a transmission input torque (Tin) and a gear change ratio (i) without causing a belt slip, set the driven pulley required axial thrust (Qdnnec) as a driven pulley target axial thrust (Qdncmd), set an axial thrust required by a driven pulley for changing the gear change ratio to the target gear change ratio (itgt) at the target gear change ratio changing rate (ditgt) by use of the driven pulley target axial thrust (Qdncmd) as a driving pulley target axial thrust (Qdrcmd), and conduct speed change control based on target supplied hydraulic pressures (Pdrsup, Pdnsup) set in response to the driven pulley target axial thrust (Qdncmd) and the driving pulley target axial thrust (Qdrcmd). Such a control system (50) for a belt-type continuously variable transmission comprises a correction section (B5) adapted to predict a hydraulic pressure decreasing amount in a prescribed time at a current hydraulic pressure changing rate based on a hydraulic pressure value detected by a hydraulic pressure sensor, and conduct a correction to increase supplied hydraulic pressure if a possible hydraulic pressure based on the predicted hydraulic pressure decreasing amount is lower than a minimum required hydraulic pressure. It should be noted that the symbols and numbers affixed in the parentheses are corresponding reference numerals and symbols of elements in the drawings of an embodiment, which will be described later.
According to the present invention, when the hydraulic pressure decreasing amount in the prescribed time is predicted with the current hydraulic pressure changing rate, and the prediction indicates that the possible hydraulic pressure may become lower than the minimum required hydraulic pressure, the correction is conducted to increase the supplied hydraulic pressure. Accordingly, control can be conducted such that the minimum required surplus pressure is constantly secured. In other words, a particular amount of extra hydraulic pressure is not continuously added to secure a regular surplus pressure, but control is conducted such that the supplied hydraulic pressure is increased only when necessary in securing the minimum required surplus pressure. Accordingly, the regularly required surplus pressure can be reduced to the minimum required amount, improvements in fuel efficiency and durability of a belt can be expected. Further, since an appropriate surplus pressure can be secured in pulsation of hydraulic pressure or instantaneous decrease in hydraulic pressure, a belt slip can be prevented, thus achieving an improvement in toughness.
Certain preferred embodiments of the present invention will hereinafter be described in detail, by way of example only, with reference to the accompanying drawings, in which:
The continuously variable transmission CVT is used for a vehicle. The input shaft 1 is connected to an output shaft of an engine ENG via a coupling mechanism CP. Motive power transmitted to the differential mechanism 8 is transmitted to left and right wheels.
The metal V-belt mechanism 10 includes the driving pulley 11 disposed on the input shaft 1, a driven pulley 16 disposed on the counter shaft 2, and a metal V-belt 15 wound around between both the pulleys 11 and 16.
The driving pulley 11 includes a fixed half pulley 12 rotatably disposed on the input shaft 1, and a movable half pulley 13 which is movable in the axial direction with respect to the fixed half pulley 12. On a lateral side of the movable half pulley 13, a driving-side cylinder chamber 14 is formed, which is surrounded by a cylinder wall 12a coupled to the fixed half pulley 12. Hydraulic pressure Pdr supplied into the driving-side cylinder chamber 14 produces a lateral pressure for moving the movable half pulley 13 in the axial direction, in other words, an axial thrust Qdr of the driving pulley.
The driven pulley 16 includes a fixed half pulley 17 fixed to the counter shaft 2, and a movable half pulley 18 which is movable in the axial direction with respect to the fixed half pulley 17. On a lateral side of the movable half pulley 18, a driven-side cylinder chamber 19 is formed, which is surrounded by a cylinder wall 17a coupled to the fixed half pulley 17. Hydraulic pressure Pdn supplied into the driven-side cylinder chamber 19 produces a lateral pressure for moving the movable half pulley 18 in the axial direction, in other words, an axial thrust Qdn of the driven pulley.
Appropriate control of hydraulic pressures Pdr and Pdn supplied to both the cylinder chambers 14 and 19 allows setting of appropriate lateral pressures to pulleys which prevents slip of the belt 15 and changes in the pulley widths of both the pulleys 11 and 16. Accordingly, the radius of the V-belt wound around the pulleys is changed, thereby allowing continuously variation of the gear change ratio.
The planetary gear type forward-reverse switching mechanism 20 has a double-pinion planetary gear train, in which a sun gear 21 is coupled to the input shaft 1, a carrier 22 is coupled to the fixed half pulley 12, and a ring gear 23 can be held in a fixed state by a reverse brake 27. The planetary gear type forward-reverse switching mechanism 20 also has a forward clutch 25 which is capable of coupling the sun gear 21 and the ring gear 23 together. When the forward clutch 25 is engaged, all the gears 21, 22, and 23 integrally rotate with the input shaft 1, and the driving pulley 11 is driven in the same direction as the input shaft 1 (forward direction). On the other hand, when the reverse brake 27 is engaged, since the ring gear 23 is held in a fixed state, the carrier 22 is driven in the opposite direction to the sun gear 21, and the driving pulley 11 is driven in the opposite direction (reverse direction) to the input shaft 1.
The main clutch 5 controls motive power transmission between the counter shaft 2 and output-side members. Engagement of the main clutch enables motive power transmission between those. Controlling its engaging force allows control of a torque transmission capacity (torque capacity) between the input side and the output side. Accordingly, when the main clutch 5 is engaged, engine output whose speed is changed by the metal V-belt mechanism 10 is transmitted to the differential mechanism 8 via gears 6a, 6b, 7a, and 7b and divided to be transmitted to the left and right wheels (not shown) by the differential mechanism 8. Further, when the main clutch 5 is released, the motive power transmission is disabled, and the transmission becomes a neutral state.
In a control system for the above-described belt-type continuously variable transmission CVT, the supplied hydraulic pressures Pdr and Pdn of the driving-side and driven-side cylinder chambers 14 and 19 are controlled to control the axial thrusts Qdr and Qdn of the driving pulley and driven pulley, thereby setting minimum axial thrusts while preventing belt slip and thereby carrying out appropriate speed change control.
In this control, various operating conditions are detected, and the control as described above is conducted on the basis of the detected operating conditions. Therefore, as shown in
A computation process of the control system 50 will be described in detail below. A transmission input torque (Tin) signal detected by the input torque detector 31 and a gear change ratio (i) signal detected by the gear change ratio detector 32 are input to a pulley required axial thrust calculation section B1. Here, in response to the input torque (Tin) and the gear change ratio (i), a driving-side pulley required axial thrust (Qdrnec) and a driven-side pulley required axial thrust (Qdnnec) are obtained as minimum required axial thrusts in the range in which belt slip is prevented.
Meanwhile, at the same time, a vehicle speed (V) signal detected by the vehicle speed sensor 33 and an engine throttle opening (th) signal detected by the engine throttle opening sensor 34 are input to a target gear change ratio calculation section B2. Here, a target gear change ratio (itgt) is obtained in response to the vehicle speed (V) and the throttle opening (th). Further, a target gear change ratio changing rate (ditgt) is obtained as a change amount per time of the target gear change ratio (itgt).
Further, the transmission input torque (Tin) signal detected by the input torque detector 31, the gear change ratio (i) signal detected by the speed change ratio detector 32, driving-side pulley required axial thrust (Qdrnec) signal and driven-side pulley required axial thrust (Qdnnec) signal that are obtained by the pulley required axial thrust calculation section B1, target gear change ratio (itgt) signal and target gear change ratio changing rate (ditgt) signal that are obtained by the target gear change ratio calculation section B2 are input to a gear change ratio control section B3. The gear change ratio control section B3, on the basis of the input signals, determines target axial thrusts (Qdrcmd and Qdncmd) of driving-side and driven-side pulleys that are required to change a current gear change ratio to the target gear change ratio (itgt) at the target gear change ratio changing rate (ditgt).
Target axial thrust signals (Qdrcmd and Qdncmd) determined in such a manner are input to a pulley supplied hydraulic pressure calculation section B4. The pulley supplied hydraulic pressure calculation section B4 obtains target supplied hydraulic pressures (Pdrsup and Pdnsup) of the driving-side and driven-side cylinder chambers 14 and 19 which are required to obtain the target axial thrusts. Specifically, the target axial thrusts (Qdrcmd and Qdncmd) are divided by the areas of the cylinder chambers 14 and 19 that receive the pressures to obtain hydraulic pressures required for the cylinder chambers. The obtained values are further corrected with hydraulic pressure variation factors to obtain the target supplied hydraulic pressures (Pdrsup and Pdnsup).
The driving-side and the driven-side target supplied hydraulic pressure signals (Pdrsup and Pdnsup) obtained in such a manner are input to an electric current conversion section B6 via a correction section B5. The electric current conversion section B6 obtains actuation control electric current signals for the speed change control valves that control the hydraulic pressures supplied to the driving-side and driven-side cylinder chambers 14 and 19. The speed change control valves are, for example, linear solenoid valves, which are controlled to operate with the control electric current obtained in the electric current conversion section B6 and control the hydraulic pressures of the driving-side and driven-side cylinder chambers 14 and 19 according to the target supplied hydraulic pressures (Pdrsup and Pdnsup). Parts of the control system 50 except for the electric current conversion section B6 are implemented by a computer included in an electronic control unit for a vehicle.
A configuration for calculating the target supplied hydraulic pressures (Pdrsup and Pdnsup) is not limited to the above-described example, but any configurations may be employed. As described later, the present invention has a feature that the correction section B5 is provided to appropriately secure the minimum required surplus pressure.
PMA=actual hydraulic pressure (detected hydraulic pressure value)−instructed hydraulic pressure value (target supplied hydraulic pressure)
Basically, the correction section B5 predicts a hydraulic pressure decreasing amount in a prescribed time (for example, 100 ms) at a current hydraulic pressure changing rate on the basis of the detected hydraulic pressure value by the hydraulic pressure sensor 35. If it is predicted that PMA (or a possible hydraulic pressure) will be lower than the minimum required hydraulic pressure, correction to increase the supplied hydraulic pressure (the target supplied hydraulic pressure Pdnsup of the driven pulley 16) is conducted.
In step S12, a determination is made about whether the current axial thrust of the driven pulley 16 has decreased to the axial thrust value of the driving pulley 11 or lower. If the determination is YES, the process progresses to step S13 and continues “PMA decreasing determination”. The current axial thrust of the driven pulley 16 is determined on the basis of the detected hydraulic pressure value of the hydraulic pressure sensor 35 for detecting the hydraulic pressure of the driven-side cylinder chamber 19. If the current axial thrust of the driven pulley 16 is not lower than the axial thrust of the driving pulley 11, since it is not necessary to consider the possibility of decrease in the surplus pressure PMA, “PMA decreasing determination” is terminated and the PMA decreased determination flag is reset.
In step S13, a PMA change amount determination reference value is obtained according to the current surplus pressure PMA (the difference between the actual hydraulic pressure and the instructed hydraulic pressure value) and an oil temperature measured by an oil temperature meter 36 (See
A method for using the map will be described. On the map, the current surplus pressure PMA is applied to the horizontal axis, the corresponding value on the vertical axis is obtained as the PMA change amount determination reference value. Then, the obtained PMA change amount determination reference value is compared with the current PMA change amount. If the current PMA change amount is equal to or less than the obtained PMA change amount determination reference value, it is predicted that the hydraulic pressure decreasing amount in the prescribed time will become lower than the minimum required hydraulic pressure. On the basis of the prediction, correction is conducted to increase the supplied hydraulic pressure. Accordingly, the function (curve) of the PMA change amount determination reference value which appears on the map represents the reference line for the determination predicting that the hydraulic pressure decreasing amount in the prescribed time becomes lower than the minimum required hydraulic pressure.
The map characteristics shown in
Since the relationship between the hydraulic pressure acting on the pulleys and the pulley axial thrusts (belt clamping force) obtained by this hydraulic pressure changes according to the change in oil viscosity depending on the oil temperature, the map characteristic shown in
Returning to
Returning to
In step S6, a hydraulic pressure addition amount base value is obtained from a prescribed map in response to the current surplus pressure PMA and PMA change amount. In step S7, a process for limiting the hydraulic pressure addition amount base value obtained in previous step S6 is conducted. Specifically, if the hydraulic pressure addition amount base value obtained in step S6 exceeds a prescribed limit value, the hydraulic pressure addition amount base value is limited so that the limit value is a maximum value. The hydraulic pressure addition amount base value, which is limited in such a manner, is set as a hydraulic pressure addition amount base restriction value.
In step S8, a routine for determination of addition amount for lower limit guaranteed hydraulic pressure is conducted, in which an addition amount for lower limit guaranteed hydraulic pressure is determined on the basis of the hydraulic pressure addition amount base restriction value obtained in previous step S7.
In
On the other hand, if the hydraulic pressure addition amount base restriction value is smaller than the previous hydraulic pressure addition amount target value, the hydraulic pressure addition amount target value is required to be reduced. The process progresses via a determination of NO in step S20 to step S24. In step S24, a check is made about whether a timer value set in previous step S21 has become zero. If the timer value has not become zero, an ongoing process ends. If the timer value has become zero, a prescribed amount is subtracted from the previous hydraulic pressure addition target value to be set as the “hydraulic pressure addition amount restriction value” in step S25. Next, in step S26, the larger value between the “hydraulic pressure addition amount base restriction value” and “hydraulic pressure addition amount restriction value” is set as a new “hydraulic pressure addition amount target value”. This moderates the change in which the hydraulic pressure addition amount target value decreases (preventing a rapid decreasing change). The hydraulic pressure (the target supplied hydraulic pressure) of the hydraulic system for producing the pulley axial thrusts is set according to the “hydraulic pressure addition amount target value” set in this step S26. The timer used in these steps provides a delay of a prescribed period in control to decrease the hydraulic pressure addition amount target value. Response delay is thereby provided in hydraulic pressure decreasing control, thus preventing shortage in the pulley axial thrusts.
Returning to
If the instructed hydraulic pressure value change amount is not larger than the prescribed value, the process progresses via a determination of NO in step S28 to step S31. In step S31, a check is made about whether a timer value set in aforementioned step S29 has become zero. If the timer value has not become zero, the process progresses to step S30 and the instructed hydraulic pressure value rapid change flag is set. If the timer value has become zero, the process progresses to step S32 and the instructed hydraulic pressure value rapid change flag is reset. This timer sustains a determination of “instructed hydraulic pressure value rapid change” for a prescribed period once the instructed hydraulic pressure value rapid change flag has been set, thereby preventing the determination of “instructed hydraulic pressure value rapid change” from unstably fluctuating.
Returning to
In
In step S35, similarly to step S12 (
When the control to cope with PMA decrease in accordance with the present invention is conducted, the surplus pressure PMA increases, and the current surplus pressure PMA becomes larger than the PMA recovered determination reference value, it is determined YES in step S37, and the process progresses to step S38. In step S38, a check is made about whether the value of the prescribed timer 2 has become zero (that is, whether time is up). If the timer value has not become zero, the PMA recovered determination flag is reset in step S41. However, if the timer value has become zero, the process progresses to step S39, and the PMA recovered determination flag is set.
Returning to
This application is based on, and claims priority to, Japanese patent application No. 2011-087805 filed on 11 Apr. 2011. The disclosure of the priority application, in its entirety, including the drawings, claims, and the specification thereof, are incorporated herein by reference.
Takayama, Hitoshi, Totsuka, Hirohiko
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
6135915, | Jul 03 1998 | Honda Giken Kogyo Kabushiki Kaisha | Method of transmission control for belt-type stepless transmission device |
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JP2000018347, | |||
JP579550, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Apr 11 2012 | Honda Motor Co., Ltd. | (assignment on the face of the patent) | / |
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