JP2005331037A - Control device for vehicle-starting friction-element - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a control device for a vehicle-starting friction-element by which even though vehicle load varies, a shock is reduced which is caused at the starting time by an abrupt increase in coupling torque of the starting friction-element such as a clutch, and occurrence of an engine stop can be controlled. <P>SOLUTION: A starting clutch control device controls coupling torque of a forward clutch 20 in accordance with input torque inputted to the forward clutch 20. The control device includes a normal coupling torque-controller, which controls coupling torque of the forward clutch 20 so that the forward clutch 20 gets into slipping at a starting time, and a coupling-torque correction means. The coupling-torque correction means exerts correction so that after a slip control of the forward clutch 20 by the normal coupling-torque controller, the coupling torque of the forward clutch 20 is enhanced higher than the coupling torque at the slip control time so that the increase rate of the coupling torque varies in response to a vehicle load. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technical field of a vehicle start friction element control device that controls a fastening torque of a start friction element in accordance with an input torque to the start friction element.

As this type of technology, the starting clutch as the starting friction element is slipped at the start to eliminate the feeling of stickiness and discomfort at the start, and when a predetermined time elapses from the start of the slip control, the torque for engaging the clutch is increased. The starting clutch is forcibly fastened so that the engine torque becomes equal to or higher than the engine torque, and abnormal heat generation of the starting clutch due to overcoming a road surface step, traveling at a steep slope, towing, etc. is prevented (see, for example, Patent Document 1) ).
Japanese Patent Laid-Open No. 8-111002

  However, in the above prior art, when a predetermined time has elapsed after the start clutch slip control has been started, the clutch engagement torque is immediately set to be larger than the engine torque, and the vehicle load is taken into consideration. Therefore, depending on the vehicle load, there is a drawback that a shock or an engine stop may occur when the clutch is engaged.

  The present invention has been made paying attention to the above problems, and its object is to provide a starting friction element due to a sudden increase in the fastening torque of a starting friction element such as a clutch at the start even when the vehicle load is different. It is an object of the present invention to provide a vehicle start friction element control device that can reduce a shock at the time of fastening and suppress the occurrence of an engine stop.

In order to achieve the above object, in the present invention, in the starting friction element control device for controlling the fastening torque of the starting friction element according to the input torque input to the starting friction element,
Normal fastening torque control means for controlling the fastening torque of the starting friction element so that the starting friction element is in a slip state at the start,
A fastening torque correction means for correcting the fastening torque after the slip control of the starting friction element by the normal fastening torque control means to be higher than the fastening torque at the time of the slip control so that the increase rate changes according to the vehicle load;
Equipped with.

  In the present invention, in the vehicle starting friction element control device, after the slip control of the starting friction element, the shock at the time of starting friction element fastening due to a sudden increase in the fastening torque of the starting friction element such as a clutch at the time of starting is reduced. In addition, the occurrence of engine stop can be suppressed.

  The best mode for carrying out the vehicle start clutch control device of the present invention will be described below with reference to the drawings.

  First, the configuration of the starting frictional element control device according to the first embodiment will be described.

  FIG. 1 is an overall system diagram showing a drive system and a control system of a vehicle equipped with a belt-type continuously variable transmission equipped with a starting friction element control device according to the first embodiment.

  A vehicle equipped with a belt-type continuously variable transmission includes an engine 1, a torsional damper 3 that reduces vibration of the engine 1, a forward / reverse switching mechanism 6 having a starting clutch, and a belt-type continuously variable transmission that continuously shifts between input and output. The transmission mechanism 19 includes an output gear 12 and a drive gear 13 that reduce the output, and left and right drive wheels 17 and 18 that are driven via a differential gear 14 and left and right drive shafts 15 and 16.

  The engine 1 is composed of a gasoline engine, a diesel engine, or the like, and the engine output shaft 2 is connected to the input portion of the torsional damper 3.

  The torsional damper 3 is configured such that an input part connected to the engine output shaft 2 and an output part connected to the clutch input shaft 5 are connected to each other via a torsion spring so as to be relatively rotatable. In addition, the flywheel 4 which rotates integrally with this is fixed to the output part.

  The forward / reverse switching mechanism 6 includes a simple planetary gear 22 capable of switching the rotation direction and the gear ratio, a forward clutch 20 that is fastened and constitutes a starting friction element of the present invention, and a forward friction that is fastened backward and is also of the present invention. And a reverse brake 21 as an element.

  The simple planetary gear 22 rotatably supports a sun gear 22s that rotates concentrically with the clutch output shaft 7, a plurality of pinions 22p that mesh with the sun gear 22s, a ring gear 22r that meshes with the pinion 22p, and the pinion. And a carrier 22c. The sun gear 22s is connected to the driven side portion of the forward clutch 20 and the clutch output shaft 7, the carrier 22c is connected to the fixed side portion of the reverse brake 21, and the ring gear 22r is connected to the drive side portion of the forward clutch 20.

  The forward clutch 20 has a plurality of plates interposed between a drive side portion connected to the clutch input shaft 5 and a driven side portion connected to the clutch output shaft 7, and applies clutch hydraulic pressure to a piston (not shown). It is possible to switch between a fastening state in which power can be transmitted between the input and output by pressing the plate, and a released state in which power cannot be transmitted to the output side part by discharging the clutch hydraulic pressure acting on the piston. .

  The reverse brake 21 has a plurality of plates interposed between an inner fixed portion of the transmission case 23 and a fixed side portion connected to the carrier 22c, and presses the plate by applying brake hydraulic pressure to a piston (not shown). It is possible to switch between a fastening state in which the integrated carrier 22c is fixed in a non-rotatable manner to the fixed side portion and a released state in which the fixed side portion and the carrier 22c can be rotated by discharging brake hydraulic pressure acting on the piston. Configured.

  The belt-type continuously variable transmission mechanism 19 continuously changes the gear ratio between the input and output shafts, and includes a primary pulley 8 connected to the clutch output shaft 7 and a secondary pulley connected to the pulley output shaft 11. 10 and a CVT belt 9 spanned between the primary pulley 8 and the secondary pulley 10. The primary pulley 8 and the secondary pulley 10 have fixed sheaves 8a and 10a, movable sheaves 8b and 10b that approach and leave the fixed sheaves 8a and 10a, respectively. A primary pulley oil chamber 33 is provided on the back surface of the movable sheave 8 b of the primary pulley 8, and the hydraulic sheave 8 b is fixed to the fixed sheave by controlling the hydraulic pressure supplied to the primary pulley oil chamber 33 by the hydraulic control unit 32. The speed is changed by moving the valve 8a relative to and away from 8a. An oil tank 30 is provided, and pressure oil obtained by sucking oil from the oil tank 30 by the oil pump 31 is supplied to the hydraulic control unit 32.

  Next, the control system of the vehicle equipped with the belt type continuously variable transmission according to the first embodiment will be described with reference to FIG.

  This control system includes an engine controller 40 that controls the engine 1, a transmission controller 41 that controls the hydraulic control unit 32 of the forward / reverse switching mechanism 6 and the belt-type continuously variable transmission mechanism 19, and sensors connected to these controllers. And.

  Connected to the engine controller 40 are a throttle opening sensor 42 for detecting the degree of depression of the accelerator pedal and an engine speed sensor 43 for detecting the speed of the output shaft 2 of the engine 1. The engine 1 is controlled using the throttle opening information and the engine speed information, and the information is output to the transmission controller 41.

  On the other hand, the transmission controller 41 is integrated with the clutch input shaft rotation sensor 48 that is integrally connected to the clutch input shaft 5 and detects the rotational speed of the drive side portion of the forward clutch 20, and the driven side portion of the forward clutch 20. A clutch output shaft rotation sensor 49 that detects the rotational speed of the connected clutch output shaft 7, a brake pedal force sensor 44 that detects the brake pedal depression force or brake fluid pressure, and a vehicle speed sensor 45 that detects the vehicle speed are connected. From these, clutch input shaft rotation information, clutch output shaft rotation information, brake pedal effort information, and vehicle speed information are input.

  The transmission controller 41 is connected to a forward clutch solenoid 46 that controls the hydraulic pressure supplied to the forward clutch 20 and a reverse brake solenoid 47 that controls the hydraulic pressure supplied to the reverse brake 21. The transmission controller 41 controls the forward clutch solenoid 46 and the reverse brake solenoid 47 so as to switch the forward clutch 20 and the reverse brake 21 to the fully engaged state, the slip state, and the released state, respectively, based on the information from the sensors. It is. The transmission controller 41 further controls the hydraulic pressure supplied to the primary pulley oil chamber 33 by a solenoid valve (not shown) provided in the hydraulic pressure control unit 32.

  An output gear 12 is fixed to an end portion of the secondary pulley shaft 11 on the secondary pulley 10 side of the belt type continuously variable transmission mechanism 19, and meshed with a drive gear 13 having a larger diameter than the output gear 12.

  Two pinions of the differential gear 14 are fixed to the drive gear 13, and side gears are engaged with these pinions from the left and right, respectively. Drive shafts 15 and 16 are connected to the side gears to drive the left and right drive wheels 17 and 18.

Next, the operation will be described.
[When the vehicle is stopped]

  When the engine 1 is stopped, the oil pump 31 is not driven and no hydraulic pressure is generated, and the hydraulic control unit 32 is not in the forward or reverse traveling state. Therefore, both the forward clutch 20 and the reverse brake 21 are released. The belt type continuously variable transmission mechanism 19 is also in a state in which power cannot be transmitted.

  When the engine 1 is operating, the oil pump 31 is driven to supply pressure oil to the hydraulic control unit 32. At this time, the engine controller 40 controls the engine 1 based on the throttle opening information input from the throttle opening sensor 42, the engine speed information input from the engine speed sensor 43, and the like. Further, when the select lever (not shown) is in a non-traveling position such as a P (park) position or an N (neutral) position, the transmission controller 32 does not supply pressure oil to the forward clutch 20 and the reverse brake 21 and releases them. Keep it in a state. Therefore, the driving force of the clutch input shaft 5 is not transmitted to the clutch output shaft 7, and the belt type continuously variable transmission mechanism 19 is not rotated. As a result, the driving force does not act on the driving wheels 17 and 18.

During the operation of the engine 1, this power is transmitted to the clutch input shaft 5 after the vibration is attenuated by the torsional damper 3. The power here is substantially equivalent to the engine torque, and corresponds to the input torque of the present invention.
[When the vehicle starts]

  When the engine 1 is in an operating state and the select lever is moved from a non-travel position to a forward travel position such as a D (drive) position, the transmission controller 41 switches a valve (not shown) in the hydraulic control unit 32. Then, control is performed so as to start supplying pressure oil to the forward clutch 20. At this time, the magnitude of the hydraulic pressure supplied to the forward clutch 20 is initially set to a hydraulic pressure lower than the complete engagement pressure until a predetermined time elapses as will be described later, and the forward clutch 20 is brought into a slip state. As a result, a part of the motive power output from the engine is changed to heat while the remaining motive power is output to the clutch output shaft 7 while avoiding the engagement shock caused by the forward clutch 20 being rapidly engaged at a high pressure.

  In this state, since the forward clutch 20 is slipping, the clutch output shaft 7 directly connected to the sun gear 22 s of the forward / reverse switching mechanism 6 and the driven side portion of the forward clutch 20 is connected to the forward / reverse switching mechanism 6. The ring gear 22r is rotated by the slip amount and the transmission power is also reduced.

  The power transmitted to the clutch output shaft 7 in this way is further transmitted to the belt type continuously variable transmission mechanism 19, where it is decelerated and output to the secondary pulley shaft 11, and then the output gear 12, the drive gear 13, and the differential. The gear 14 and the drive shafts 15 and 16 are transmitted to the drive wheels 17 and 18 through these in this order. As a result, the vehicle starts and moves forward. In this forward travel position, no pressure oil is supplied to the reverse brake 21, and the reverse brake 21 is in a released state.

  After the first predetermined time has elapsed since the slip control was started, the transmission controller 41 receives the clutch input shaft rotation information obtained from the clutch input shaft rotation sensor 48 and the clutch output shaft obtained from the clutch output shaft rotation sensor 49. Based on the rotation information, the difference between the input and output rotational speeds of the forward clutch 20 is calculated, the hydraulic pressure supplied to the forward clutch 20 is gradually raised according to the input and output rotational speed differences, and finally the magnitude that does not slip, that is, Control is made to a fully engaged state where the clutch engaging torque is greater than the engine torque. Details of this control will be described later.

  On the other hand, when the select lever is moved from the non-traveling position to the R (reverse) position, the transmission controller 41 switches the valve in the hydraulic control unit 32 to a pressure lower than the hydraulic pressure required for complete engagement with the reverse brake 21. Oil is supplied until a second predetermined time has elapsed. As a result, the reverse brake 21 transmits the remaining power to the clutch output shaft 7 while changing a part of the power output from the engine 1 by slipping into heat.

  That is, in this state, since the carrier 22c rotates with the brake applied, a part of the motive power transmitted from the engine 1 to the clutch input shaft 5 and the ring gear 22r integrated therewith via the carrier 22c. The reverse brake 21 is brought into a slip state, and the remaining power is transmitted from the ring gear 22r to the sun gear 22s through the pinion 22p. The rotation direction of the sun gear 22s is opposite to the rotation direction of the clutch input shaft 5. . The power transmitted to the sun gear 22s is transmitted to the drive wheels 17 and 18 via the clutch output shaft 7, the belt type continuously variable transmission mechanism 19 and the like. In this reverse position, no hydraulic pressure is supplied to the forward clutch 20, and the forward clutch 20 is in a released state.

Even at the time of reverse, the hydraulic pressure supplied to the reverse brake 21 is gradually raised after the second predetermined time has elapsed since the start of slip control, as in the case of forward start. It is concluded.
[When the vehicle is running after starting]

  As described above, when the first predetermined time elapses after starting at the forward travel position, the transmission controller 41 controls the valve of the hydraulic control unit 32 to change the hydraulic pressure supplied to the forward clutch 20 to the clutch input / output rotational speed difference. The forward clutch 20 is brought into a completely engaged state without slip so that the clutch engagement torque in the forward clutch 20 becomes equal to or higher than the engine torque.

  In this state, the sun gear 22s of the forward / reverse switching mechanism 6 has the same rotational speed as that of the ring gear 22r, and these rotate together with the carrier 22c. Therefore, the clutch output shaft 7 rotates in the same direction and at the same rotational speed as the clutch input shaft 5, and the power of the engine 1 is input to the belt type continuously variable transmission mechanism 19 as it is.

  The transmission ratio of the belt-type continuously variable transmission mechanism 19 is controlled by the transmission controller 41. That is, the target gear ratio is determined based on the vehicle speed information obtained from the vehicle speed sensor 45 by the transmission controller 41, the throttle opening information and the engine speed information obtained from the engine controller 40, and the target gear ratio is set. The hydraulic pressure supplied to the primary oil chamber 33 is adjusted, and the movable sheaves of the primary pulley 8 and the secondary pulley 10 are displaced. The output of the belt-type continuously variable transmission mechanism 19 obtained according to this gear ratio is transmitted to the left and right drive wheels 17 and 18 via the output gear 12, the drive gear 13, the differential gear 14, and the drive shafts 15 and 16. Then, the drive wheels 17 and 18 are driven to drive the vehicle forward.

  On the other hand, during reverse travel, when the second predetermined time has elapsed after slipping the reverse brake 21 and the second predetermined time has elapsed, the transmission controller 41 controls the valve of the hydraulic control unit 32 to clutch the hydraulic pressure supplied to the reverse brake 21. The reverse brake 21 is increased according to the input / output rotational speed difference, and finally the reverse brake 21 is brought into a completely engaged state without slip so that the brake torque at the reverse brake 21 becomes equal to or higher than the engine torque.

  In this fully engaged state, the power input from the engine 1 as it is is transmitted to the ring gear 22r of the forward / reverse switching mechanism 6 connected to the clutch input shaft 5, but on the non-rotatable carrier 22c. The pinion 22p is rotated, and the sun gear 22s meshing with the pinion 22p is rotated at a reverse speed. This reversed output is input to the belt type continuously variable transmission mechanism 19 and transmitted to the drive wheels 17 and 18 as in the case of the forward traveling, although the rotational direction is different.

  [Clutch engagement torque correction control process]

  FIG. 2 is a flowchart showing a flow of the above-mentioned starting clutch control process executed by the transmission controller 41. Each step will be described below. Although only the start control of the forward clutch 20 will be described here, the same control logic as the start clutch start control is basically used for the reverse clutch 21 although the set values such as a predetermined time are different.

  In step S101, the clutch heat generation amount Q in the forward clutch 20 is calculated, and the process proceeds to step S102. Here, the clutch heat generation amount Q is calculated from the clutch engagement torque, the elapsed time from the start of clutch engagement, and the difference between the rotational speeds of the clutch input shaft 5 and the clutch output shaft 7. The clutch engagement torque is estimated by measuring and calculating the hydraulic pressure supplied to the clutch and brake.

In step S102, it is determined whether or not the clutch heat generation amount Q of the forward clutch 20 has exceeded a preset clutch engagement torque correction control start value Q ₁ (t). If NO, the process proceeds to step S103, and YES is determined. In this case, the process proceeds to step S104. The clutch engagement torque correction control start value Q ₁ (t) constitutes the first threshold value of the present invention.

  In step S103, the clutch engagement torque command value Tc is set lower than the engine torque Te to the normal control clutch engagement torque command value Tc1 at which the forward clutch 20 enters the slip state, and the process proceeds to step S105. Here, step S103 executed by the transmission controller 41 constitutes the normal fastening torque control means of the present invention.

  On the other hand, in step S104, the clutch engagement torque command value Tc is set to a corrected control clutch engagement torque command value Tc2 obtained by correcting the normal control clutch engagement torque command value Tc1, and the process proceeds to step S105. In addition, step S104 performed by the transmission controller 41 comprises the fastening torque correction means of this invention.

  Here, the corrected control clutch engagement torque command value Tc2 is a value obtained by integrating the normal control clutch engagement command value Tc1 with a variable α taking into account the vehicle load such as vehicle weight and road surface gradient, and the clutch engagement torque from the time of normal control. The forward clutch 20 is set so as to increase to a magnitude equal to or greater than the engine torque so that the forward clutch 20 is completely engaged. The vehicle load is estimated based on the input / output rotational speed difference of the forward clutch 20.

  In step S105, the clutch input / output rotational speed difference Δω between the clutch input shaft 5 and the clutch output shaft 7 based on the clutch input / output shaft rotational speed information obtained from the clutch input shaft rotational sensor 48 and the clutch output shaft rotational sensor 49. Is determined to be approximately 0, the process ends if YES, and returns to step S101 if NO.

  FIG. 3 is a graph showing the relationship between the clutch engagement torque control time t from the start of the starting clutch control, the clutch heat generation amount Q, the clutch input / output shaft rotational speed difference Δω, and the like.

As shown in the figure, the time period from when the clutch engagement torque control time t starts to control the clutch engagement torque by starting until the clutch heat generation amount Q exceeds the clutch engagement torque correction control start value Q ₁ (t) When 0 ≦ t <t ₁ , normal clutch engagement torque control is performed such that the clutch engagement torque Tc1 is smaller than the engine torque Te and the forward clutch 20 is in a slip state, and the clutch heat generation amount Q is the clutch engagement torque correction control start value Q ₁ ( In a time period t ₁ ≦ t <t ₂ exceeding t), clutch engagement torque correction control for increasing the clutch engagement torque is performed. Then, the clutch engagement torque correction control ends at time t ₂ when the clutch input / output shaft rotational speed difference Δω becomes substantially zero.

Hereinafter, the normal clutch engagement torque control and the clutch engagement torque correction control will be described in detail.
[Normal clutch engagement torque control]

  In the normal clutch engagement torque control, the clutch engagement torque command value Tc1 is set so that the clutch engagement torque gradually increases with the passage of the clutch engagement torque control time t from the time of forward start by the engagement of the forward clutch 20. However, the clutch engagement torque command value Tc1 is set to be smaller than the engine torque so that the forward clutch 20 is in a slip state. Due to this clutch engagement torque command value Tc1, the supply pressure to the forward clutch 20 is increased and the clutch output shaft rotational speed increases greatly. As a result, the increase rate of the clutch input / output shaft rotational speed difference Δω decreases. Go.

  Thus, in the normal clutch engagement torque control, the forward clutch 20 is slip-controlled, so that the forward clutch 20 generates heat due to the slip of the clutch, and the clutch heat generation amount Q increases. In this case, as the clutch engagement torque control time t elapses, the slip amount of the clutch decreases, so that the clutch heat generation amount Q increases while the increase rate decreases.

After the time t _{1 when the} normal clutch engagement torque control is continued and the clutch heat generation amount Q becomes larger than the clutch engagement torque correction control start value Q ₁ (t), the normal clutch engagement torque control is changed to the clutch engagement torque correction control described below. And can be switched. Note that the clutch engagement torque correction control start value Q ₁ (t) for determining an increase in clutch engagement torque is set so as to gradually decrease as the elapsed time increases.
[Clutch engagement torque correction control]

  In the clutch engagement torque correction control, control is performed using a correction control clutch engagement torque command value Tc2 instead of the normal clutch engagement torque control command value Tc1. The correction control clutch engagement torque command value Tc2 is the product of the normal control clutch engagement torque Tc1 and the clutch engagement torque correction rate α. Here, the clutch engagement torque correction rate α is changed as needed under the following conditions.

  (1) The clutch engagement torque correction rate α is determined by the clutch input / output shaft rotational speed difference Δω, the clutch engagement torque control time t, and the engine torque Te.

  (2) The clutch engagement torque correction rate α is set higher as the clutch input / output shaft rotation speed difference Δω increases, and the clutch engagement torque correction rate α is set smaller as the clutch input / output shaft rotation speed difference Δω decreases.

  (3) The clutch engagement torque correction rate α is set higher as the clutch control time t becomes longer.

  (4) The clutch engagement torque correction rate α is set lower as the engine torque Te is smaller.

  (5) The clutch engagement torque correction rate α is determined by the clutch input / output shaft rotational speed difference Δω, the clutch engagement torque control time t, and the engine torque Te as shown in (1) to (4) above. The rate of increase of the control clutch engagement torque (the slope of the curve C1 in FIG. 3) is set to be larger (the slope of the curve C2 in FIG. 3), and the rate of increase gradually increases with the elapsed time. .

  As shown in FIG. 4, the transmission controller 41 is created corresponding to the magnitude of each engine torque Te1 to Ten, and determines a correction control clutch engagement torque command value Tc2 (= αTe1 (Δω, t)). N maps M1 to Mn are stored in advance. That is, each map M1 to Mn is based on the clutch engagement torque control time t from the start of the starting clutch control, the clutch input / output shaft rotation speed difference Δω, and the clutch engagement torque correction rate α, and the correction control clutch engagement at the engine torque. The torque command value Tc2 is determined.

  Note that the curve C1 composed of the normal control clutch engagement torque command value Tc1 and the curve C2 composed of the correction control clutch engagement torque command value Tc2 shown in FIG. 3 are set so as to be connected continuously and smoothly.

  In this clutch engagement torque correction control, as shown in FIG. 3, the correction control clutch engagement torque command value Tc2 is set larger than the value of the clutch engagement torque command value Tc1 and the engine torque. The increasing rate of the clutch heat generation amount Q decreases, the clutch output shaft rotational speed increases, and the clutch input / output shaft rotational speed difference Δω decreases.

As a result, the forward clutch 20 is quickly activated so as to prevent the forward clutch 20 from becoming abnormally high temperature while avoiding the occurrence of a large fastening shock due to sudden engagement with the clutch fastening torque that is raised according to the vehicle load or the like. Fully fastened. Complete engagement is carried out in time t _2, thereafter the state continues.

  Next, the effect of the starting friction element control device of the first embodiment will be described.

(1) When the clutch heat generation amount Q exceeds the clutch engagement torque correction control start value Q ₁ (t), the clutch engagement torque is not suddenly completely engaged but increased at a rate corresponding to the vehicle load. Since the clutch slip amount is increased, the clutch engagement shock can be reduced even for different vehicle loads, and the clutch heat generation amount Q can be increased as the clutch engagement torque increases. The rate of increase can be reduced. Therefore, deterioration of the members constituting the clutch can be suppressed, and seizure of the clutch can be avoided. It should be noted that the clutch engagement torque is increased until it becomes equal to or higher than the engine torque to completely engage the clutch, thereby eliminating clutch slip and completely suppressing heat generation due to slip in the clutch.

  (2) The clutch engagement torque correction rate α is set so as to increase as the clutch engagement torque input / output shaft rotational speed difference Δω increases, and the increase rate of the correction control clutch engagement torque command value Tc2 is increased. Since the rate of increase in the calorific value Q can be reduced, deterioration of the members constituting the clutch can be suppressed and the seizure of the clutch can be avoided even when the vehicle load is different.

  (3) Since the clutch engagement torque correction rate α is set higher and the increase rate of the correction control clutch engagement torque Tc2 is increased as the clutch control time t becomes longer, the increase rate of the clutch heat generation amount Q can be lowered. In addition, deterioration of members constituting the clutch can be suppressed, and the seizure of the clutch can be avoided.

  (4) When the clutch input shaft torque (equal to the engine torque Te in this embodiment) is small, the clutch engagement torque correction rate α is set small, and conversely when the clutch input shaft torque is large, the clutch engagement torque correction rate α is increased. Because it is set, it is possible to obtain a clutch engagement torque according to the magnitude of the clutch input shaft torque. Even if the vehicle load and the clutch input shaft torque are different, the clutch is reduced while reducing the shock at the time of clutch engagement. It is possible to suppress deterioration of members constituting the clutch and to avoid clutch burn-in.

(5) The clutch engagement torque correction control start value Q ₁ (t) is set so as to decrease as the clutch engagement torque control time t elapses. Can be avoided.

  (6) As shown in FIG. 3, when switching from the normal torque engagement torque control to the clutch engagement torque correction control, the clutch engagement torque command value Tc1 is determined from the curve C1 during the clutch engagement torque normal control. Since the control is performed so that the vehicle load is continuously and smoothly transferred to the hour curve C2, the occurrence of a shock at the time of switching the clutch engagement torque control can be suppressed.

The overall system of the vehicle equipped with a belt type continuously variable transmission provided with the starting clutch control device of the second embodiment is the same as that of the first embodiment of FIG. 1, but the control is different. That is, in the starting clutch control device of the second embodiment, the transmission controller 41 has the clutch engagement torque release control start value Q ₂ (t), and the clutch heat generation amount Q is the clutch engagement torque release control start value Q. Control is performed so that the forward clutch 20 is released when ₂ (t) is exceeded. In addition, about the structure similar to Example 1, the code | symbol same as Example 1 is attached | subjected and those description is abbreviate | omitted. The clutch engagement torque release control start value Q ₂ (t) constitutes the second threshold value of the present invention.

  Next, the operation will be described.

In the starting clutch control device according to the second embodiment, the clutch engagement torque control time t is the clutch engagement torque correction control start value Q ₁ (t) after the clutch engagement torque control time t starts the engagement control of the forward clutch 20. When the time zone until the time exceeds 0 ≦ t ≦ t ₃ , normal clutch engagement torque control is performed to bring the forward clutch 20 into the slip state, and the clutch heat generation amount Q is set to the clutch engagement torque correction control start value Q ₁ (t). In the time zone t ₃ <t, the clutch engagement torque correction control is started. Here, the clutch engagement torque correction control start value Q ₁ (t) is set to become lower as the clutch engagement torque control time t elapses as shown in FIG.

In the clutch engagement torque correction control, as in the first embodiment, the clutch engagement torque correction rate α determined in accordance with the vehicle load is corrected so that the clutch engagement torque is larger than that during normal clutch engagement torque control, and is started up. It will increase until it becomes larger than the engine torque. In this case, when the clutch heat generation amount Q reaches the clutch engagement torque release control start value Q ₂ (t), the forward clutch 20 is released by the clutch engagement torque release control, and the forward clutch 20 is prevented from becoming excessively hot. Incidentally, the clutch engagement torque clutch engagement torque release control start value Q ₂ (t) is set higher than the clutch engagement torque correction control start value Q ₁ (t), similarly to the clutch engagement torque correction control start value Q ₁ (t) In addition, the clutch engagement torque control time t is set so as to decrease as the time elapses.

  FIG. 6 is a flowchart showing the flow of the starting clutch control process executed by the transmission controller 41 similar to that in FIG. 1 of the second embodiment. Each step will be described below.

  In step S201, as in the case of the first embodiment, the clutch heat generation amount Q of the forward clutch 20 is calculated, and the process proceeds to step S202. Here, the clutch heat generation amount Q is calculated from the clutch engagement torque, the elapsed time from the start of clutch engagement, and the difference in rotational speed between the clutch input shaft 5 and the clutch output shaft 7.

In step S202, it is determined whether or not the clutch heat generation amount Q of the forward clutch 20 has exceeded the clutch engagement torque correction control start value Q ₁ (t). If NO, the process proceeds to step S203. If YES, the process proceeds to step S203. The process proceeds to S204.

  In step S203, the clutch engagement torque command value Tc is set to the normal control clutch engagement torque command value Tc1 that causes the forward clutch 20 to slip, and the process proceeds to step S207. Here, step S203 executed by the transmission controller 41 constitutes the normal fastening torque control means of the present invention.

On the other hand, in step S204, it is determined whether or not the clutch heat generation amount Q of the forward clutch 20 exceeds the clutch engagement torque release control start value Q ₂ (t). If NO, the process proceeds to step S205, and YES is determined. In this case, the process proceeds to step S206. The clutch engagement torque release control start value Q ₂ (t) is set higher than the clutch engagement torque correction control start value Q ₁ (t) as shown in FIG. 5, and the clutch engagement torque correction control start value Q ₁ (t In the same manner as (), the clutch engagement torque control time t is set to decrease with the passage of time. Further, step S205 executed by the transmission controller 41 constitutes the fastening torque correction means of the present invention.

  In step S205, the clutch engagement torque command value Tc is set to a corrected control clutch engagement torque command value Tc2 obtained by correcting the normal control clutch engagement torque command value Tc1, and the process proceeds to step S207. The corrected control clutch engagement torque command value Tc2 is a value obtained by integrating the normal control clutch engagement torque command value Tc1 with a variable α taking into account the vehicle load such as the vehicle weight and the road surface gradient, and an increase rate corresponding to the vehicle load. The clutch engagement torque is set so as to be large enough to rise and be equal to or greater than the clutch input torque.

  In step S206, the forward clutch 20 is released and the process ends.

  In step S207, it is determined whether or not the clutch input / output rotational speed difference Δω between the clutch input shaft 5 and the clutch output shaft 7 has become substantially 0. If YES, the process ends. If NO, the process returns to step S201.

  Next, the effect will be described.

  The starting clutch control device of the second embodiment can obtain the same effects as those of the first embodiment, and can also obtain the following effects. That is,

(7) If the vehicle load is large, the clutch heat generation amount Q may continue to increase even if the clutch engagement torque correction control is performed, but the clutch heat generation amount Q is determined to be equal to the clutch engagement torque release control value Q ₂ (t). If it exceeds, the forward clutch 20 is released, so that the increase of the clutch heat generation amount Q is stopped, the deterioration of the clutch constituent members can be suppressed, and the burning of the clutch can be avoided.

(8) Since the clutch engagement torque correction control start value Q ₂ (t) is set to become lower as the clutch engagement torque control time t elapses, deterioration of the clutch components due to the prolonged clutch slip control. Can be avoided more reliably.

  The vehicle starting clutch control device of the present invention has been described based on the first and second embodiments. However, the specific configuration is not limited to these embodiments, and each claim of the claims is described below. Changes and additions in the design are allowed without departing from the gist of the invention according to the section.

  For example, in the first and second embodiments, the clutch heat generation amount is calculated from the clutch engagement torque, the elapsed time from the start of clutch engagement, and the difference between the clutch input rotation speed and the clutch output rotation speed. Further, a sensor or the like that directly measures the clutch temperature or the like may be used. In the first and second embodiments, the vehicle load is determined as the clutch input / output shaft rotational speed difference Δω, the clutch engagement torque control time t, and the engine torque. However, the vehicle load may be estimated or detected by another method. Further, the present invention is not limited to the forward clutch, but may be a starting frictional element such as a reverse brake.

  The starting friction element control device of the present invention is not limited to a vehicle equipped with a belt-type continuously variable transmission, but also a vehicle equipped with a stepped automatic transmission, a vehicle equipped with a toroidal continuously variable transmission, a vehicle equipped with an automatic MT, a hybrid vehicle, an electric vehicle, etc. In short, the present invention can be applied to various vehicles having a friction element that is fastened when starting and transmits input torque from a driving source.

1 is an overall system diagram illustrating a vehicle equipped with a belt-type continuously variable transmission to which a starting clutch control device according to a first embodiment is applied. 3 is a flowchart showing a starting clutch control process executed by the transmission controller according to the first embodiment. It is a time chart of Example 1 characteristics of clutch input / output rotation speed, clutch heat generation amount, engine torque, and clutch engagement torque at the time of start. 6 is a map for determining a clutch engagement torque correction rate α. It is a time chart of Example 2 characteristics of clutch input / output rotation speed, clutch heat generation amount, engine torque, and clutch engagement torque at the time of start. 7 is a flowchart showing a start clutch control process executed by a transmission controller according to a second embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Engine 2 Engine output shaft 3 Torsional damper 4 Flywheel 5 Transmission input shaft 6 Forward / reverse switching mechanism 7 Primary pulley shaft 8 Primary pulley 9 CVT belt 10 Secondary pulley 11 Secondary pulley shaft 12 Output gear 13 Drive gear 14 Differential gear 15 , 16 Drive shaft 17, 18 Drive wheel 20 Forward clutch 21 Reverse brake 22 Simple planetary gear 23 Transmission case 30 Oil tank 31 Oil pump 32 Hydraulic control unit 33 Primary pulley oil chamber 40 Engine controller 41 Transmission controller 42 Throttle opening sensor 43 Engine speed sensor 44 Brake pedal force sensor 45 Vehicle speed sensor 46 Forward clutch solenoid 47 Reverse brake solenoid 48 Clutch input shaft rotation Sensor 49 clutch output shaft rotation sensor

Claims (9)

In the starting friction element control device for controlling the fastening torque of the starting friction element according to the input torque input to the starting friction element,
Normal fastening torque control means for controlling the fastening torque of the starting friction element so that the starting friction element is in a slip state at the time of starting;
Fastening torque correcting means for correcting the fastening torque after the slip control of the starting friction element by the normal fastening torque control means so as to be higher than the fastening torque at the time of the slip control so that the increasing rate changes according to the vehicle load. When,
A starting friction element control device for a vehicle, comprising: The vehicle starting friction element control device according to claim 1,
In the vehicle, the fastening torque correction by the fastening torque correcting means increases the fastening torque as the difference between the input rotational speed of the starting friction element and the output rotational speed of the starting friction element increases. Starting friction element control device. In the vehicle starting friction element control device according to claim 1 or 2,
The fastening torque correction by the fastening torque correcting means increases the fastening torque as the elapsed time from the start of the slip control becomes longer. In the vehicle start friction element control device according to any one of claims 1 to 3,
The vehicle starting friction element control device is characterized in that the fastening torque correction by the fastening torque correcting means increases the fastening torque as the input torque to the starting friction element increases. In the vehicle start friction element control device according to any one of claims 1 to 4,
The fastening torque correction by the fastening torque correction means is performed by the amount of heat generated by the starting friction element estimated from the difference between the rotational speed between the input rotational speed of the starting friction element and the output rotational speed of the starting friction element and the fastening torque. A starting frictional element control device for a vehicle, wherein the fastening torque is increased when a predetermined first threshold value is exceeded. In the vehicle starting friction element control device according to claim 5,
The vehicle start friction element control device according to claim 1, wherein the first threshold value is set to be lower as the elapsed time from the start of the slip control of the start friction element becomes longer. The vehicle starting friction element control device according to any one of claims 1 to 6,
The fastening torque is corrected by the fastening torque correcting means when the difference between the input rotational speed to the starting friction element and the output rotational speed of the starting friction element becomes substantially 0 or when the accelerator pedal is released. In addition, the vehicle starting friction element control device is characterized in that it is terminated. The vehicle starting friction element control device according to any one of claims 1 to 6,
The amount of heat generated by the starting friction element estimated from the rotational speed difference between the input rotational speed to the starting friction element and the clutch output rotational speed of the starting friction element and the clutch engagement torque is a predetermined second threshold. A starting friction element control device for a vehicle, wherein the starting friction element is released when a value is exceeded. In the vehicle start friction element control device described in claim 8,
The starting friction element control device for a vehicle, wherein the second threshold value is set to be lower as the elapsed time from the start of the slip control of the starting friction element becomes longer.

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