JP2010210008A - Control device for lock-up clutch of vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent shocks caused when releasing a lock-up clutch by carrying out foot lifting from an accelerator pedal during control of the lock-up clutch. <P>SOLUTION: The control device for the lock-up clutch of a vehicle includes the lock-up clutch, and a controller controlling a capacity of the lock-up clutch. In the controller, a capacity command value P<SB>L(c)</SB>is lowered to a preset first predetermined value P<SB>1</SB>by foot lifting from the accelerator pedal, control is carried out so as to retain a state of lowering it to the first predetermined value P<SB>1</SB>until a predetermined time t<SB>0</SB>, the capacity command value P<SB>L(c)</SB>is controlled, after the predetermined time t<SB>0</SB>has passed, so as to raise it to a second predetermined value P<SB>2</SB>larger than the first predetermined value P<SB>1</SB>and smaller than a capacity P<SB>0</SB>at foot lifting, and thereafter the capacity command value P<SB>L(c)</SB>is gradually lowered and, in conjunction therewith, an engine is controlled such that engine torque T<SB>e</SB>during a time t<SB>1</SB>becomes larger than the first predetermined value P<SB>1</SB>. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a vehicle that can release a lock-up clutch by commanding the capacity of a lock-up clutch disposed in a power transmission system between an engine and a drive wheel by releasing a foot from an accelerator pedal. The present invention relates to a control device for a lock-up clutch.

  In the conventional lockup clutch control device, when the foot is released from the accelerator pedal during the slip control of the lockup clutch, the engine torque rapidly decreases while the torque capacity of the lockup clutch increases rapidly. Since a shock is generated by sudden engagement (lock-up) of the lock-up clutch, when the rate of decrease of the throttle opening exceeds a predetermined value, the lock-up clutch is suddenly released (for example, Patent Document 1). reference).

JP-A-6-221424

  However, even when the lock-up clutch is suddenly released as in the past, if the lock-up is in progress, the capacity of the lock-up clutch is increasing. Considering the value delay, it may not be possible to prevent the progress to lockup. In this case, as a result of being locked up, a shock is caused.

  On the other hand, when the lock-up clutch can be released suddenly following the command value, the engine torque suddenly decreases on the input side of the lock-up clutch, while the output from the automatic transmission etc. The torque fluctuation is small because there is no fluctuation in the load. For this reason, a so-called torque step may occur before and after sudden release in the lockup clutch. In this case, if the torque step is large, there is a concern that this torque step will be felt as a shock as a result.

  According to the present invention, when the lockup clutch capacity is decreased in response to the release from the accelerator pedal and the clutch is to be released quickly, the lockup clutch capacity is not reduced at a stroke until a torque step occurs. In other words, the capacity is controlled so that the lockup clutch is actually released after being quickly reduced to a capacity that does not cause a torque step.

  In the present invention, it is possible to quickly release the lockup clutch when the foot is released from the accelerator pedal, while suppressing a torque step caused by releasing the lockup clutch to a small level. For this reason, even when there is a release from the accelerator pedal, the lock-up clutch can be released smoothly.

1 is a system diagram schematically showing a power train of a vehicle equipped with a lockup clutch control device according to one embodiment of the present invention, together with a control system thereof. It is a flowchart which shows the flow of control performed by the control apparatus of the same form. It is a determination map used for lockup capacity command control concerning the control device of the same form. It is a time chart when performing lockup capacity command control concerning the control device of the same form. It is a time chart when other lockup capacity command control concerning the control device of the form is performed. It is a time chart when performing lockup capacity control as a comparative example with lockup capacity command control concerning the control device of the same form.

  Hereinafter, a lockup capacity control apparatus according to the present invention will be described in detail with reference to the drawings.

1 shown in FIG. 1 is an engine. The engine 1 has a throttle valve 11 whose opening increases in accordance with the depression amount of the accelerator pedal 10. Throttle valve 11 is introduced into the engine 1 by the air amount corresponding air from the air cleaner 12 to the throttle opening TVO and the engine speed N _e.

The engine 1 has an injector 13 and an ignition device 14 for each cylinder, and the fuel injection amount and the ignition timing are controlled by the engine controller 9a. The engine controller 9a, for example, a signal from an engine rotation sensor S _e that detects the engine speed N _e, the signal I from the idle switch S _w which is released by releasing the foot from the accelerator pedal 10 _(a), a signal from the intake air amount sensor S _Q for detecting an engine intake air amount Q is input.

The engine controller 9a controls the fuel injection amount (fuel supply amount) into each cylinder by controlling the injector 13 according to the operating state based on such various input information (input signals). For example, the engine controller 9a performs so-called fuel cut control for stopping the fuel supply into the cylinder to the engine 1 by controlling the injector 13 when the foot is released from the accelerator pedal 10.
Alternatively, so-called fuel cut recovery control for restarting fuel supply is performed for the purpose of preventing engine stall or the like.

  Further, the engine controller 9a controls the ignition timing in each cylinder by controlling the ignition device 14 in accordance with the operating state based on the above input information. For example, when the foot from the accelerator pedal 10 is released, the engine controller 9a controls the ignition device 14 to perform ignition delay control that delays the ignition timing in the cylinder for the engine 1.

  Reference numeral 2 denotes a torque converter to which rotation from the engine 1 is input. The torque converter 2 transmits the rotation of the input side element (pump impeller) 2a that is drivingly coupled to the engine 1 to the output side element (turbine runner) 2b that is drivingly coupled to the automatic transmission 2 via the internal working fluid. To do.

Reference numeral 3 denotes an automatic transmission into which the engine rotation N _e is input via the torque converter 2. The automatic transmission 3 is a so-called stepped automatic transmission in which a predetermined shift stage is selected by a combination of ON and OFF in shift solenoids 4 a and 4 b provided in the control valve unit 4.

  The output rotation of the automatic transmission 3 is transmitted from the transmission output shaft (propeller shaft) 5 to the wheels 7 via the differential gear mechanism 6.

Reference numeral 8 denotes a lock-up clutch built in the torque converter 2. The capacity (hereinafter referred to as “lock-up capacity”) P _L of the lock-up clutch that controls engagement (hereinafter “lock-up”) and release (hereinafter “lock-up release”) of the lock-up clutch 8 is the control valve unit 4. This is determined by controlling the lockup solenoid 4c provided in the control unit 4 according to the drive duty command D.

When the lockup capacity P _L is determined to be 0, a state where the input / output elements of the torque converter 2 are not fastened at all, that is, a so-called converter state is set. On the other hand, when the lockup capacity P _L is increased, a state where the input / output elements of the torque converter 2 are fastened, that is, a so-called lockup state is obtained.

  Note that the lock-up is a so-called complete lock in which the input / output elements are completely fastened so that no slip rotation occurs due to the magnitude relationship between the transmission torque between the input / output elements of the torque converter 2 and the lock-up capacity. Up and a so-called slip lock-up state where the input / output element is smoothly fastened while slipping.

The ON / OFF of the shift solenoids 4a and 4b and the drive duty command D of the lock-up solenoid 4c are controlled by the transmission controller 9b. The transmission controller 9b includes, for example, a signal I from the idle switch _{Sw (a)} , a signal from the throttle opening sensor S _Th that detects the throttle opening TVO of the throttle valve 11, and an input rotation of the torque converter 2. the number (hereinafter, "impeller rotational speed") N and the signal from the impeller rotation sensor S _{i of i} to detect the output rotational speed of the torque converter 2 (hereinafter, "turbine speed") turbine speed sensor for detecting the N _t S _{t is determined} by the signal from _t , the signal from the transmission output rotation sensor S _o for detecting the rotation speed of the transmission output shaft 5 (hereinafter referred to as “transmission output shaft rotation speed”) N _o , and the driver's selection. The signal from the inhibitor switch Sw _(b) that outputs the shift range (for example, P (parking) range, D (driving) range, N (neutral) range, L (engine brake) range)) Enter each one.

The transmission controller 9b performs shift control of the automatic transmission 3 as follows based on these input information by a known calculation. First the vehicle speed VSP determined from the transmission output speed N _o, on the basis of the shift map event from the throttle opening TVO, to find a suitable gear position for the current vehicle operating conditions, shifting to the preferred gear position Is performed so that the shift solenoids 4a and 4b are switched on and off.

The transmission controller 9b further checks whether or not the torque increase function and the torque fluctuation absorption function of the torque converter 2 are unnecessary from the above input information, and the duty (D) of the lockup solenoid 4c based on the determination result. via control, the lock-up state between input and output elements are directly coupled by (increase of the lockup capacity P _L) engagement of the lockup clutch torque converter 2 if the lock-up region, the lockup clutch if the other converter region Is released (decrease in the lockup capacity P _L ) so that the direct connection between the input and output elements is released.

The lock-up state is executed under constant speed driving at a high vehicle speed that does not require a torque increasing action and a torque fluctuation absorbing action. The lock-up state, under the coasting running the fuel cut, in order to prevent engine stall, the rotation N _o of the transmission output shaft 5 is performed to transfer to the engine 1. The lock-up in this case is particularly called coast-up lock-up.

  Between the engine controller 9a and the transmission controller 9b, bidirectional communication is possible, and coordinated control is performed to execute fuel cut or fuel cut recovery for the engine 1 in accordance with the engagement and release of the lockup clutch 8. And

  Next, referring to the flowchart of FIG. 2, the lockup capacity control at the time of transition from the slip engagement state at the time of driving to the slip engagement state at the time of coasting performed according to the present invention, and the engine side performed in synchronization with the control The cooperative control in will be described.

In the control according to the present invention, first, in step 1, it is determined whether or not the automatic transmission 3 is controlled according to the shift control in the D range. In this embodiment, this determination is performed by the transmission controller 9b to which the signal from the inhibitor switch Sw _(b) is input, and when it is determined that it is in the D range, the process proceeds to step 2, but otherwise If it is determined that it is within the range, the process returns as it is.

In step 2, it is determined whether or not the accelerator pedal 10 has been released. In this embodiment, this determination is performed by the engine controller 9a to which the ON / OFF signal I from the idle switch S _{w (a)} is input. When the idle switch S _{w (a)} is turned on, the determination is made in step 3. However, when the accelerator pedal 10 is depressed and the idle switch Sw _(a) is OFF, the routine returns as it is.

  In step 3, it is determined whether smooth lock-up is being performed, or whether complete lock-up has just started. In this embodiment, this determination is performed by the transmission controller 9b, and if it is determined that slip lockup is in progress or complete lockup has started, the process proceeds to step 4, but otherwise, it is left as it is. Return.

In step 4, it is determined whether or not the vehicle speed VSP is equal to or less than a threshold vehicle speed _Vth . In this embodiment, this determination is performed by the transmission controller 9b, by comparing the vehicle speed VSP computed based on the transmission output shaft speed N _o from a transmission output rotation sensor S _o with the threshold speed V _th If it is determined that the vehicle speed VSP is equal to or less than the threshold vehicle speed _Vth , the process proceeds to step 5; otherwise, the process returns.

As the threshold vehicle speed V _th , for example, a value set in advance on the low vehicle speed side for the purpose of improving fuel efficiency can be cited. With this setting, in step 4 of this embodiment, it can be determined whether or not the vehicle is in a low vehicle speed state immediately after starting. However, the threshold vehicle speed V _th is not only set for the purpose of improving fuel efficiency, but can be appropriately set according to, for example, engine performance, vehicle type, driver's request, and the like.

In step 5, the operation progress of the lock-up clutch 8 after releasing the foot from the accelerator pedal 10 is estimated. This estimation is performed by the transmission controller 9b. In the transmission controller 9b, the engine speed N _e detected by the engine speed sensor S _e, obtains the rotational difference ΔN (= N _e -N _i) by subtracting the impeller rotational speed Ni detected from the impeller rotation sensor S _i, The above estimation is performed by determining the region using the map shown in FIG. 3 together with the capacity command value (hereinafter referred to as “capacity command value”) P _{L (c)} to the lock-up clutch 8 commanded immediately before releasing the foot. .

  In this embodiment, the map shown in FIG. 3 is divided into three areas A to C.

If the area A is a capacity related to the capacity command value P _{L (c)} in this area, even if the lockup is released when the foot is released from the accelerator pedal 10, the area A does not generate a shock due to a torque step. When there is a release from the accelerator pedal 10 while the capacity command value P _{L (c)} is being monitored, this is an area where the lockup may be released as it is.

As a specific example of the region A, as shown in FIG. 3, a range equal to or less than a necessary coast lockup capacity command value P _AB for generating a minimum lockup capacity P _{L (min)} required for coast lockup. In this case, a region that is the entire region of the rotation deviation ΔN is given.

Thereby, in step 5a, referring to the map of FIG. 3, the state (point) determined by the rotation deviation ΔN and the capacity command value P _{L (c)} when the foot is released from the accelerator pedal 10 is determined. It is determined whether it exists in the area A. This determination is made by the transmission controller 9b, and when the point is in the region A, if there is a release from the accelerator pedal 10, the lockup may be released as it is, in step 5b. The lock-up is performed by normal smooth-off control (for example, as shown in FIG. 6, when the idle switch Sw (a) is turned on, it is rapidly decreased by a certain capacity difference ΔP and then gradually decreased). To release. However, when the point does not exist in the area A, the process proceeds to step 5c.

  Next, a region B in FIG. 3 is a region in which a fastening shock is not generated even when the lock-up is to be released even if the lock-up should be released by releasing the foot from the accelerator pedal 10, that is, as it is. Even if the lockup is performed, there is no fastening shock, and even if the lockup is subsequently released, the region does not generate a shock due to the torque step.

As a specific example of the region B, as shown in FIG. 3, the capacity command value P _{L (c)} is equal to or greater than the necessary coast lockup capacity command value P _AB and is set to a preset lockup capacity command value (hereinafter referred to as “setting”). The command value is a range that is equal to or less than P _BC and the rotation deviation ΔN is in a range that is equal to or greater than a preset rotation deviation (hereinafter, “set rotation deviation”) ΔN _BC . Incidentally, each set command value P _BC and set rotational deviation .DELTA.N _BC, for example, can be appropriately set according to the engine performance, vehicle type and driver's request or the like.

Thereby, in step 5c, with reference to the map of FIG. 3, the state (point) determined by the rotational deviation ΔN and the capacity command value P _{L (c)} when the foot is released from the accelerator pedal 10 is determined. It is determined whether or not it exists in the area B. This determination is also performed by the transmission controller 9b, and when it is determined that the point is in the region B, after the lockup is performed as it is, a shock is not generated even if the lockup is released. In step 5d, normal smooth-on control (for example, as shown in FIGS. 4 and 5, control for gradually increasing the lockup capacity P to lock up before the idle switch Sw (a) is turned on. ) To lock up. However, when the point does not exist in the region B, the process proceeds to step 5e.

  Region C generates a fastening shock when locked up by releasing the accelerator pedal 10, and generates a shock due to a torque step even when the lockup is released by releasing the accelerator pedal 10. That is, this is a region where some shock is generated when the lockup capacity control is performed as it is.

As a specific example of the region C, as shown in FIG. 3, the rotation deviation ΔN is in a range where the capacity command value P _{L (c)} is not less than the necessary coast lockup capacity command value P _{AB and not} more than the set command value P _BC. Is a range that is less than or equal to the set rotation deviation ΔN _{BC, and in} the range where the capacity command value P _{L (c)} is greater than or equal to the set command value P _BC, an area that is the entire area of the rotation deviation ΔN is included.

Thus, when the process proceeds to step 5e, a state (point) determined by the rotational deviation ΔN and the capacity command value P _{L (c)} when the foot is released from the accelerator pedal 10 is present in the area C of the map. judge. This determination is also performed by the transmission controller 9b, and when it is determined that the point is in the region C, if there is a release from the accelerator pedal 10, the lockup capacity control is performed as it is. It is estimated that a shock will occur, and the routine proceeds to step 6.

  In step 6, the engine 1 and the lockup clutch 8 are substantively controlled.

  In step 6a, lock-up release control is performed by releasing the foot from the accelerator pedal 10. This control is performed when the transmission controller 9b determines that the determination result in step 5 is the region C.

That is, in step 6a, if the lockup capacity control is performed as it is, it is presumed that some kind of shock will occur. Therefore, as shown in FIG. 4, the capacity command value P _{L (c)} is set to a first set value P that is set in advance. _The capacity command value P is controlled so that it is controlled to be lowered to ₁ and the state lowered to the first set value P ₁ is maintained until a predetermined time t ₀ from when the first set value P ₁ is commanded. Control _{L (c)} . That is, when the idle switch S _{w (a)} is turned ON, capacity command value P _{L (c),} after decreasing rapidly to the first set value P _1, a predetermined time the state of the first set value P ₁ Control is performed to hold up to t ₀ .

The control for reducing the capacity command value P _{L (c)} to the first set value P ₁ is a control for rapidly reducing the capacity command value P _{L (c)} to a capacity that does not cause a torque step between the lockup latches 8. The first set value P ₁ is a capacity command value in consideration of a delay in the actual capacity (hereinafter referred to as “actual capacity”) P _L of the lockup clutch 8 with respect to the capacity command value P _{L (c)} . This value is set to execute processing for improving responsiveness by setting PL _(c) to be low, so-called advance processing.

For this reason, when the capacity command value P _{L (c)} is rapidly decreased to the first set value P ₁ , feedforward control is used. Further, the first set value P ₁ can be appropriately set according to engine performance, vehicle type, driver's request, and the like. Specific examples include a numerical value of about 0 to 0.02 MPa.

On the other hand, at the predetermined time t ₀ , the actual release operation of the lockup clutch 2 follows the capacity command value P _{L (c)} for quickly decreasing to a capacity at which no torque step occurs. It is a grace time considering up to. The predetermined time t ₀ can be set as a time during which it can be estimated that the actual lockup release operation will follow the capacity command value P _{L (c)} . Therefore, the predetermined time t ₀ can be appropriately set according to, for example, engine performance, vehicle type, driver's request, and the like.

Further, after the predetermined time t ₀ has elapsed, in step 6a, as shown in FIG. 4, the capacity command value P _{L (c)} is larger than the first set value P ₁ and the lockup capacity P ₀ when the foot is released. (In this embodiment, control is further performed so as to increase to a second set value P ₃ which is smaller than a set value P ₂ described later). After commanding the second set value P ₃ as the capacity command value P _{L (c)} is controlled to gradually decrease with the gradual slope of the capacity command value P _{L (c).} Thereby, the control for actually releasing the lockup is performed in a state where the actual capacity P _L follows the capacity command value P _{L (c)} .

If the capacity command value P _{L (c)} is controlled in this way, the accelerator pedal 10 is suddenly released while the capacity command value P _{L (c)} is being increased as the lock-up progresses. Accordingly, even if the lockup is stopped and released, the responsiveness of the lockup clutch 8 is emphasized, and even if the capacity command value P _{L (c)} is not rapidly decreased until a large torque step occurs, The lockup clutch 8 can be released.

Moreover, upon urgently release the lock-up by reducing drastically the capacity command value P _{L (c)} with the release of the lock-up, the capacity command value P _{L (c) is} the actual capacity P _L capacity command value even if P L _(c) as delayed with respect, during the waiting time for a predetermined time t _0, it becomes possible to eventually follow by catch up to the capacity command value P _{L (c).}

  As a result, the lock-up clutch 8 can be quickly released while suppressing a so-called torque step caused by releasing the lock-up clutch 8. For this reason, even when there is a release from the accelerator pedal 10, the lock-up clutch 8 can be released smoothly.

Further, in this embodiment, after raised to a second predetermined value P _3, since to have a lamp (inclined) to gradually decrease the lockup capacity P _L, the lockup capacity P _L comes out completely The lockup capacity P _L is suddenly reduced (so that it becomes 0 MPa), but the timing of this reduction is when the preset time ΔT is reached from when the idle switch _{Sw (a)} is turned on. It can also be lowered when the lock-up capacity P _L reaches a preset third hydraulic pressure P ₄ . Further, in this case, the set time ΔT and the third set value P ₄ can also be set as appropriate according to the engine performance, the vehicle type, the driver's request, and the like.

Further, as in the present embodiment, using the map of FIG. 3, the lockup clutch 8 is determined by the rotational speed deviation Δ and the lockup capacity command value P _{L (c)} when the idle switch _{Sw (a)} is turned on. If it is presumed that some sort of shock will occur when operating toward release, the lock-up clutch 8 will release the lock-up release control executed by releasing the foot, which is executed in step 6a. The lock-up release control control in a state where no shock is generated even if the fastening is performed as it is can be omitted.

Here, referring to the time chart of the comparative example shown in FIG. 6, in the lockup capacity control at the time of transition from the slip engagement state at the time of driving to the slip engagement state at the coast time, normally, as shown in a region Z ₁ of FIG. The engine speed N _e and the engine torque _Te are highly responsive to foot release from the accelerator pedal 10.

Therefore, as shown in region Z ₃ in FIG. 6, when to release the lockup clutch 8 according to foot release from the accelerator pedal 10, as large torque difference between the lockup clutch 8 is not generated, If the command P _{L (c)} = P ₂ is commanded as the capacity command value P _{L (c)} so that the lock-up capacity P _L is rapidly decreased by ΔP, the lock-up clutch 8 originally does not produce a large torque step. It is released immediately.

However, as shown in FIG. 6, for example, the lockup clutch 8 is engaged / released even when the lockup is released by abruptly decreasing the capacity command value P _{L (c)} while the lockup is in progress. When the actual capacity P _L is a hydraulic medium, there is a case where the decrease in the actual capacity P _L cannot follow the command for rapidly decreasing the actual capacity P _L from the capacity command value P _{L (c)} .

In this case, the torque capacity of the lockup clutch 8 (hereinafter, "lockup torque") decrease in T _LC is also delayed with respect to capacity command value P _{L (c)} with actual capacity PL result, the lockup torque T _LC , it delayed than the decrease of the engine torque T _e. For this reason, reduction of the lockup torque T _LC is unable to firmly follow the reduction of the engine torque T _e.

Therefore, the locus lockup clutch 8, in practice, as shown in region Z ₂ in the figure, with the locus in association with the change of the engine torque T _e (dotted line in the figure) to a change in the lockup torque T _LC As is clear from the fact that it intersects (dotted line in the figure), it is locked up because the progress of the lockup cannot be stopped. Thus, as shown in FIG. 6, when the capacity command value P _{L (c)} is controlled, a large fastening shock is generated as shown in a region Z ₄ of FIG.

In contrast, the control apparatus of this embodiment, as shown in a region X ₁ in FIG. 4, an engine speed N _e and the engine torque T _e is a good response to foot release from the accelerator pedal 10.

Moreover, the control apparatus of this embodiment, as shown in the figure, when it is intended to release the lock-up in the lock-up progress, as shown in a region X _3, capacity command value P _{L (c)} a first after rapidly decreased to a set value P _1, since the holding state to the first set value P ₁ a capacity command value P _{L (c)} until the predetermined time t _0, the capacity P _L is a hydraulic medium Also, until the predetermined time t ₀ elapses, the actual capacity P _L follows the capacity command value P _{L (c)} .

In this case, it decreases from that no delay with respect to capacity command value P _{L (c)} with the decrease also actual capacity PL of lockup torque T _LC, with lockup torque T _LC also the engine torque T _e. In other words, the firm can follow the decrease is also a decrease in engine torque T _e of the lockup torque T _LC.

Thus, the actual lock-up clutch 8 also, as shown in a region X ₂ in the figure, the trajectory due to the change of the engine torque T _e (dotted line in the figure) the locus with changes in lockup torque T _LC (Fig. As is clear from the fact that it does not intersect with the middle one-dot chain line), the progress of the lock-up is stopped and the lock-up is also released.

That is, according to the control apparatus of the present embodiment, as shown in region X ₄ in FIG. 4, even when a torque step by the lock-up is released during the lock-up progresses, due to the torque difference The lock-up clutch 8 can be released while suppressing the occurrence of shock. The capacity P ₂ can be set to a value that does not cause a large torque step when the lockup clutch 8 is released. For example, the capacity P ₂ can be appropriately set according to engine performance, vehicle type, driver's request, and the like. it can.

Meanwhile, the engine controller 9b of this embodiment share the information of the lock-up capacity P _L and the transmission controller 9b. Therefore, in step 6b described with reference to FIG. 2, it is possible to perform cooperative control on the engine 1 in conjunction with the lockup release control in step 6a. Hereinafter, as the cooperative control, as described above, a case where the fuel cut control and the fuel cut recovery control executed by the engine controller 9a are executed together will be described as a second mode.

In this embodiment, the engine torque _Te is controlled so as to be larger than the first set value P ₁ until a certain time t ₂ elapses after the idle switch _{Sw (a)} is turned on. As a specific example, as shown in FIG. 4, the engine 1 is controlled so that the engine torque _Te becomes a value T ₁ (= P ₁ + h) obtained by adding a hysteresis value h to the first set value P ₁ . The engine torque T _1, a value obtained by a hysteresis pressure h of the lockup capacity P _L and the like of the actual lockup capacity P _L.

The time t ₂ to keep increasing the engine torque T _e is also a previously set time can also be determined in accordance with the lockup capacity information of the P _L from the transmission controller 9b.

As described above, when the cooperative control for the engine 1 is performed in conjunction with the lockup release control by releasing the foot, the fuel cut control (fuel injection control) is executed by releasing the foot from the accelerator pedal 10, so that the engine torque T _{Even when e} rapidly decreases, the decrease can be suppressed. For this reason, if the cooperative control for the engine 1 is also performed, even if the input side load of the lockup clutch 8 decreases due to the release from the accelerator pedal 10, the accelerator pedal is not performed without performing the cooperative control for the engine 1 together. The decrease can be suppressed as compared with the case where it is simply decreased by releasing the foot from 10.

That is, in conjunction with the lock-up release control by releasing the foot, the engine torque _Te is set to be larger than the first set value P ₁ until a predetermined time t ₂ has elapsed from the releasing of the accelerator pedal 10. by controlling the engine torque T _e, that tends to occur slippage between the input and output of the lock-up clutch 8, since the improved control over the lock-up clutch 8 is effective in preventing the occurrence of shock.

Here, referring to the time chart according to the present embodiment shown in FIG. 5, in the control device of the present embodiment, the same control as in the first embodiment is executed for the capacity command value P _{L (c)} . as shown in a region Y ₂ of the drawing, the cooperative control for the engine 1 is not running. Therefore, in the first embodiment, while the engine torque T _e decreases relatively rapidly, in the present embodiment, reduction of the engine torque T _e is not generated until the predetermined time t _2.

That is, the actual lock-up clutch 8 also, as shown in a region Y ₂ of the drawing, the trajectory due to the change of the engine torque T _e (dotted line in the figure) the locus with changes in lockup torque T _LC (Fig. a one-dot chain line) in it, in comparison with the first embodiment (see region X ₂ in FIG. 4), as is apparent from the fact that more apart, it can stop the progress of the lock-up more reliably Yes.

In addition, the code | symbol G of FIGS. 4-6 is the acceleration at the time of vehicle advance. _{Symbol TLC} and symbol _TTC are the transmission torque and lockup capacity torque of the torque converter 2, respectively, and the added values are indicated by broken lines.

  Furthermore, in each of the above embodiments, the engine controller 9a and the transmission controller 9b correspond to lockup clutch control means and engine torque control means, respectively. In this embodiment, the engine controller 9a and the transmission controller 9b are provided as separate bodies, but may be a single controller.

DESCRIPTION OF SYMBOLS 1 Engine 2 Torque converter 2a Pump impeller 2b Turbine runner 3 Automatic transmission 4 Control valve unit 4a Shift solenoid 4b Shift solenoid 4c Lockup solenoid 5 Transmission output shaft 6 Differential gear mechanism 7 Wheel 8 Lockup clutch 9a Engine controller 9b Transmission Controller 10 Accelerator pedal 11 Throttle valve 12 Air cleaner 13 Injector 14 Ignition device S _{w (a)} Idle switch S _{w (b)} Inhibitor switch S _Th throttle opening sensor S _i impeller rotation sensor S _t turbine rotation sensor S _o Transmission output rotation Sensor

Claims (3)

A lock-up clutch that is placed in the power transmission system between the engine and the drive wheels and is engaged when the capacity increases, and is released when the capacity decreases, and locks up when the foot is released from the accelerator pedal. Lockup clutch control means for controlling the clutch capacity to decrease,
The lock-up clutch control means instructs to reduce the capacity to the first set value set in advance by releasing the accelerator pedal and to hold the state reduced to the first set value for a predetermined time. And, after the lapse of the predetermined time, command control to increase the capacity of the lock-up clutch to a second set value that is larger than the first set value and smaller than the capacity when the foot is released, Thereafter, a control device for a lockup clutch of the vehicle, which performs command control to gradually decrease the capacity.   The engine torque for command-controlling the engine torque according to claim 1, in conjunction with the lock-up clutch control means, so that the engine torque during a predetermined time after the release from the accelerator pedal becomes larger than the first set value. A control device for a lockup clutch of a vehicle, comprising a control means.   3. The lockup clutch control means according to claim 1 or 2, wherein the lockup clutch control means estimates the operation progress of the lockup clutch after releasing the foot, and when it is estimated that a shock occurs if the lockup clutch operates as it is, A control device for a lockup clutch of a vehicle, which starts capacity control.

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