JP2007155081A - Hydraulic control device for automatic transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce cost for a device and simplify an oil path. <P>SOLUTION: When an on-off solenoid valve 60 is energized, first hydraulic pressure output from a control valve 70 is supplied through a relay valve 50 to a lockup clutch 14 and modulator pressure Pm is supplied through the relay valve 50 to a first assist chamber 33a of a first regulator valve 30. When the on-off solenoid valve 60 is not energized, the first hydraulic pressure output from the control valve 70 is cut off from the communication with the lockup clutch 14 by the relay valve 50 and second hydraulic pressure output from a linear solenoid valve 80 is supplied through the relay valve 50 to the first assist chamber 33a of the first regulator valve 30. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a hydraulic control device for an automatic transmission, and more particularly to a hydraulic control device for an automatic transmission that can reduce the cost of the device and simplify an oil passage.

  Recently, in a hydraulic control device for an automatic transmission, so-called clutch-to-clutch control has been adopted to pursue a smooth and highly responsive shift feeling, and one electronic valve has been arranged for each engagement element. ing. On the other hand, since the cost increases when the computerization is advanced, the cost is reduced by sharing the electromagnetic valve. For example, in Patent Documents 1 and 2, a solenoid valve (control valve) that controls a lock-up clutch (L / U) using a relay valve (shift valve) and a solenoid valve (control valve) that controls a clutch that obtains a desired gear stage. ) Is disclosed, and Patent Document 3 discloses a technique in which a solenoid valve (control valve) for controlling a regulator valve and a modulator valve (control valve) are shared.

JP-A-4-145262 JP-A-10-246320 JP-A-7-113466

  However, since the number of control valves included in the automatic transmission is limited, there is a limit to sharing the control valves.

  The main subject of this invention is aiming at the cost reduction of an apparatus, and the simplification of an oil path.

  Here, the shift control valve connected to the engagement element is switched by a shift valve, and the line pressure is communicated to the engagement element in a required shift pattern as a substitute for the shift control valve, thereby reducing the number of shift control valves. Cost reduction. However, as a price, it will not be possible to perform a jumping shift.

Therefore, the shift control valve is not shared, and the L / U control valve and the line pressure control control valve are shared. However, in consideration of a normal disconnection failure, an NL (normal low) type is used as the L / U control valve, which has a low pressure when not energized. On the other hand, if the control valve for line pressure control is an NL type, the spring constant and load variation of the spring will increase due to the stepping and load increase of the regulator valve valve, and not only the pressure tolerance will increase, but also the assembly performance will be increased. Use NH (normally high), which is a high pressure when not energized to reduce the spring load, as it will be significantly worse. Therefore, since the L / U control valve is a control valve having a characteristic different from that of the NL type and the line pressure control valve is different from the NH type, it is difficult to share the control valve.
In order to solve the above problems, the following inventions have been made.

  According to a first aspect of the present invention, there is provided a hydraulic control device for an automatic transmission including a torque converter having a lock-up clutch, and adjusts a line pressure supplied from an oil pump according to a spool position, A first regulator valve having an assist chamber for assisting urging of the spring against the spool from a spring receiving side by input of hydraulic pressure; and a relay valve for switching an oil passage leading to the lockup clutch according to the position of the spool; The line pressure is introduced, the output pressure is output according to the energized state, and the on / off solenoid valve for switching the position of the spool of the relay valve, and the first hydraulic pressure from the line pressure is determined according to the position of the spool. The control valve to be generated and the modulator pressure are introduced, and A linear solenoid valve that outputs the second hydraulic pressure and controls the position of the spool of the control valve, and the relay valve switches an oil passage that communicates with the assist chamber according to the position of the spool. When the on / off solenoid valve is energized, the first hydraulic pressure output from the control valve is supplied to the lockup clutch through the relay valve, and the modulator pressure is supplied through the relay valve. When the on-off solenoid valve is supplied to the assist chamber and the on-off solenoid valve is in a non-energized state, the first hydraulic pressure output from the control valve is disconnected from the lockup clutch by the relay valve, and the linear solenoid valve The second oil output from There characterized in that it is configured to be supplied to the assist chamber through the relay valve.

  According to a second aspect of the present invention, there is provided a hydraulic control device for an automatic transmission including a torque converter having a lock-up clutch, and adjusts the line pressure supplied from the oil pump according to the position of the spool, A first regulator valve having an assist chamber for assisting urging of the spring against the spool from a spring receiving side by input of hydraulic pressure; and a relay valve for switching an oil passage leading to the lockup clutch according to the position of the spool; The modulator pressure is introduced, the third hydraulic pressure is output according to the energized state, the on-off solenoid valve for switching the position of the spool of the relay valve, and the first hydraulic pressure from the line pressure according to the position of the spool. Control valve and modulator pressure are introduced, and A linear solenoid valve that outputs a second hydraulic pressure according to the amount and controls the position of the spool of the control valve, and the relay valve communicates with the assist chamber according to the position of the spool. The first hydraulic pressure output from the control valve is supplied to the lockup clutch through the relay valve and output from the on / off solenoid valve when the on / off solenoid valve is energized. The third hydraulic pressure is supplied to the assist chamber through the relay valve, and the first hydraulic pressure output from the control valve is applied to the lock-up clutch by the relay valve when the on / off solenoid valve is in a non-energized state. And communication with Characterized in that said second hydraulic pressure output from NIYA solenoid valve is arranged to be supplied to the assist chamber through the relay valve.

  In the hydraulic control apparatus for an automatic transmission according to the present invention, the line pressure supplied from the first regulator valve is regulated and output toward the inlet of the torque converter according to the position of the spool, and A fourth hydraulic pressure chamber that regulates the fourth hydraulic pressure that flows out from the outlet of the torque converter, outputs it to the relay valve, and presses the spool in the direction opposite to the direction in which the spring is urged against the spool when the hydraulic pressure is input. 2 regulator valves and a cooler for cooling the hydraulic oil, and the relay valve is configured to switch an oil path leading to the first regulator valve, the second regulator valve, and the cooler according to the position of the spool. And when the on-off solenoid valve is energized and the lockup clutch is engaged, the torque is The fourth hydraulic pressure that has flowed out from the outlet of the converter is discharged from the discharge port through the second regulator valve and the relay valve, and the fifth hydraulic pressure that is output from the first regulator valve as part of the line pressure is By being supplied to the hydraulic chamber of the second regulator valve through the relay valve, the sixth hydraulic pressure output from the second regulator valve toward the inflow port of the torque converter is kept low, and the on-off solenoid valve When the lockup clutch is in a non-engaged state while the power is not energized, the fourth hydraulic pressure flowing out from the outlet of the torque converter is supplied to the cooler through the second regulator valve and the relay valve. It is preferable.

  According to the present invention (Claim 1-3), linear solenoids having different characteristics can be shared, the regulator valve can be appropriately sized, and the cost can be reduced and the oil passage can be simplified. . That is, the linear solenoid valve used for controlling the first regulator valve and the linear solenoid valve used for controlling the lockup clutch can be shared.

(Embodiment 1)
A hydraulic control device for an automatic transmission according to Embodiment 1 of the present invention will be described with reference to the drawings. FIG. 1 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to Embodiment 1 of the present invention.

  A hydraulic control device 1 for an automatic transmission has a gear stage switched by a combination of supply and discharge of hydraulic pressure to a plurality of friction engagement elements, and includes a torque converter having a lock-up clutch. It is. The hydraulic control device 1 for an automatic transmission includes a torque converter 10, an oil pump 20, a first regulator valve 30, an accumulator 40, a relay valve 50, an on / off solenoid valve 60, a control valve 70, and a linear solenoid valve. 80.

  The torque converter 10 is provided in an automatic transmission (not shown), and includes a pump 11, a turbine 12, a stator 13, and a lockup clutch 14. Torque converter 10 transmits the output of an output shaft (not shown) of an engine (not shown) to a transmission mechanism (not shown). In the torque converter 10, hydraulic fluid supplied from a second regulator valve (not shown) is introduced from between the pump 11 and the stator 13, and hydraulic fluid flows out between the turbine 12 and the stator 13 to provide the second regulator valve. Return to (not shown). In order to avoid power transmission loss due to fluid slip, the lock-up clutch 14 transmits power by directly connecting the pump 11 on the input side and the turbine 12 on the output side when the rotational difference between the two is small. When the hydraulic oil supplied from the relay valve 50 is introduced, the lock-up clutch 14 is engaged by receiving the pressure of a lock-up piston (not shown).

  The oil pump 20 is a pump that pumps oil in an oil pan (not shown) toward the first regulator valve 30.

  The first regulator valve 30 is a valve that regulates the hydraulic pressure supplied from the oil pump 20, and the regulated hydraulic pressure (line pressure PL) is turned on / off by the solenoid valve 60, the feedback chamber 31a, and other not shown. A part of the regulated hydraulic pressure (line pressure PL) (fifth hydraulic pressure) is output to the second regulator valve (not shown) and output to the hydraulic control circuit. Return to the oil pan (not shown) of the pump 20. The first regulator valve 30 includes a spool 31, a spring 32, a first assist valve 33, and a second assist valve 34. The spool 31 is slidably inserted in a valve body (not shown) and is pushed toward the spring 32 by the hydraulic pressure (feedback pressure) in the feedback chamber 31a. The spring 32 is disposed between the spool 31 and the first assist valve 33, and biases the spool 31 toward the feedback chamber 31a. The first assist valve 33 is disposed between the spool 31 and the second assist valve 34, and also serves as a spring receiver for the spring 32. The hydraulic pressure (first assist pressure) supplied from the relay valve 50 is supplied to the first assist chamber 33a. As a result of the input, the spring 32 is moved to the feedback chamber 31a side to assist the biasing of the spring 32. The second assist valve 34 is configured such that the hydraulic pressure (R pressure; second assist pressure) supplied from a manual valve (not shown) in the reverse range (R range) is input to the second assist chamber 34a. The spring 32 is moved to the feedback chamber 31a side through the assist valve 33 to assist the biasing of the spring 32.

  The accumulator 40 is a device that relieves hydraulic shock by operating the relay valve 50 and the like, and is disposed on an assist oil passage 41 that communicates from the relay valve 50 to the first assist chamber 33a.

  The relay valve 50 is a lock-up relay valve that switches an oil path to the lock-up oil path 54 that communicates with the lock-up clutch 14, and has a function of switching an oil path to the assist oil path 41 that communicates with the first assist chamber 33a. The relay valve 50 includes a spool 51, a spring 52, and a hydraulic chamber 53. The spool 51 is slidably inserted in a valve body (not shown). The spring 52 biases the spool 51 toward the hydraulic chamber 53 side. In the hydraulic chamber 53, when the on / off solenoid valve 60 is not energized, the control oil pressure from the on / off solenoid valve 60 is introduced to move the spool 51 toward the spring 52, and when the on / off solenoid valve 60 is energized, the control oil pressure is turned on / off. The spool 51 is discharged by the solenoid valve 60 and moved to the hydraulic chamber 53 side. The relay valve 50 communicates the control valve 70 and the lockup clutch 14 when the on / off solenoid valve 60 is energized, and communicates the discharge port EX and the lockup clutch 14 when the on / off solenoid valve 60 is deenergized. The relay valve 50 communicates a modulator valve (not shown) that outputs a modulator pressure Pm when the on / off solenoid valve 60 is energized with the first assist chamber 33a of the first regulator valve 30 so that the on / off solenoid valve 60 is in communication. When the power is not energized, the linear solenoid valve 80 and the first assist chamber 33a of the first regulator valve 30 are communicated.

  The on / off solenoid valve 60 switches its operating state by switching the hydraulic pressure supplied to the hydraulic chamber 53 of the relay valve 50 in accordance with energization or non-energization. A line pressure PL from the first regulator valve 30 is introduced into the on / off solenoid valve 60. The on / off solenoid valve 60 is a normal high type (NH) that supplies hydraulic pressure (third hydraulic pressure) to the relay valve 50 in a non-energized state and does not supply hydraulic pressure to the relay valve 50 in an energized state. The on / off solenoid valve 60 discharges the hydraulic pressure in the hydraulic chamber 53 of the relay valve 50 when energized. Energization / non-energization of the on / off solenoid valve 60 is controlled by an electronic control unit (not shown).

  The control valve 70 introduces a line pressure PL (D pressure) output from a manual valve (not shown) in the D range via a shift valve (not shown) and controls the control oil pressure from the introduced line pressure PL. (First hydraulic pressure) is generated and output. The control valve 70 includes a spool 71, a spring 72, a hydraulic chamber 73, and a feedback chamber 74. The spool 71 is slidably inserted in a valve body (not shown). The spring 72 biases the spool 71 toward the hydraulic chamber 73 side. In the hydraulic chamber 73, when the linear solenoid valve 80 is not energized, the control hydraulic pressure from the linear solenoid valve 80 is introduced to move the spool 71 toward the spring 72, and when the linear solenoid valve 80 is energized, the control hydraulic pressure is linear. The spool 71 is discharged by the solenoid valve 80 and moved to the hydraulic chamber 73 side. The control hydraulic pressure generated from the line pressure PL is input to the feedback chamber 74 through the feedback oil passage. The control valve 70 connects the relay valve 50 and the discharge port EX when the linear solenoid valve 80 is energized, and directs the control hydraulic pressure generated from the line pressure PL to the relay valve 50 when the linear solenoid valve 80 is not energized. Output.

  The linear solenoid valve 80 adjusts the operating state of the control valve 70 in accordance with the energization amount. The linear solenoid valve 80 is introduced with a modulator pressure Pm from a modulator valve (not shown). The linear solenoid valve 80 outputs a line pressure PL (second hydraulic pressure) in a non-energized state, and outputs a regulated pressure (second hydraulic pressure) that decreases as the energized current increases in the energized state. It is. The linear solenoid valve 80 is energized by an electronic control unit (not shown).

  Next, the operation of the hydraulic control device for the automatic transmission according to the first embodiment of the present invention will be described.

(Operation 1-1)
When the on / off solenoid valve 60 is not energized, the control hydraulic pressure (L / U pressure) controlled by the linear solenoid valve 80 and the control valve 70 is cut off by the relay valve 50, and the residual pressure of the lockup clutch 14 is changed to the lockup oil. Since the exhaust is communicated with the exhaust port EX of the relay valve 50 through the passage 54, the lockup clutch 14 is disengaged. Further, since the output pressure from the linear solenoid valve 80 is input to the first assist chamber 33a of the first regulator valve 30 through the relay valve 50 and the assist oil passage 41, the line pressure of the first regulator valve 30 can be controlled. become.

(Operation 1-2)
When the on / off solenoid valve 60 is energized, the control hydraulic pressure (L / U pressure) controlled by the linear solenoid valve 80 and the control valve 70 is supplied to the lockup clutch 14 through the relay valve 50 and the lockup oil passage 54, and is locked. The up clutch 14 is engaged. Further, since the modulator pressure from the modulator valve (not shown) is input to the first assist chamber 33a of the first regulator valve 30 through the relay valve 50 and the assist oil passage 41, the line pressure PL is kept at the maximum state. Be drunk.

  When the ON / OFF solenoid valve 60 is turned ON (failed while being energized), if the linear solenoid valve 80 is energized, the lockup clutch 14 is disengaged, and if the linear solenoid valve 80 is deenergized. The lockup clutch 14 is engaged.

  Further, when the on / off solenoid valve 60 is in an OFF failure (failure in a non-energized state), the lock-up clutch 14 is disengaged regardless of whether the linear solenoid valve 80 is energized or de-energized.

  Further, when the linear solenoid valve 80 is in an ON failure, the control hydraulic pressure (L / U pressure) is not output, so that the lockup clutch 14 is disengaged.

  Further, when the linear solenoid valve 80 fails, the lockup clutch 14 is engaged when the on / off solenoid valve 60 is energized, and the lockup clutch 14 is not engaged when the on / off solenoid valve 60 is deenergized. It becomes.

  According to the first embodiment, the linear solenoid valve used for controlling the first regulator valve 30 and the linear solenoid valve used for controlling the lockup clutch 14 can be shared, and the cost of the apparatus can be reduced. In addition, the lockup clutch 14 can be disengaged regardless of which of the on / off solenoid valve 60 and the linear solenoid valve 80 fails, and the engine stall can be prevented.

(Embodiment 2)
A hydraulic control device for an automatic transmission according to Embodiment 2 of the present invention will be described with reference to the drawings. FIG. 2 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to the second embodiment of the present invention.

  In the hydraulic control device for an automatic transmission according to the second embodiment, the oil passage configuration is different from the point that an NL (normal low) type is used for the on / off solenoid valve 60. Other points are the same as in the first embodiment.

  The first regulator valve 30 does not output the regulated hydraulic pressure (line pressure PL) toward the on / off solenoid valve 60.

  The relay valve 50 communicates the control valve 70 and the lockup clutch 14 when the on / off solenoid valve 60 is energized, and communicates the discharge port EX and the lockup clutch 14 when the on / off solenoid valve 60 is deenergized. The relay valve 50 allows the on / off solenoid valve 60 to communicate with the first assist chamber 33a of the first regulator valve 30 when the on / off solenoid valve 60 is energized, and the linear solenoid valve when the on / off solenoid valve 60 is not energized. 80 communicates with the first assist chamber 33a of the first regulator valve 30.

  The on / off solenoid valve 60 is a normal low type (NL) that supplies hydraulic pressure to the relay valve 50 in an energized state and does not supply hydraulic pressure to the relay valve 50 in a non-energized state. The on / off solenoid valve 60 supplies the control hydraulic pressure not only to the hydraulic chamber 53 of the relay valve 50 but also to the switching circuit related to the assist oil passage 41 in an energized state. The on / off solenoid valve 60 discharges the hydraulic pressure in the hydraulic chamber 53 of the relay valve 50 in a non-energized state.

  Next, the operation of the hydraulic control device for an automatic transmission according to the second embodiment of the present invention will be described.

(Operation 2-1)
When the on / off solenoid valve 60 is not energized, the control hydraulic pressure (L / U pressure) controlled by the linear solenoid valve 80 and the control valve 70 is cut off by the relay valve 50, and the residual pressure of the lockup clutch 14 is changed to the lockup oil. Since the exhaust is communicated with the exhaust port EX of the relay valve 50 through the passage 54, the lockup clutch 14 is disengaged. Further, since the output pressure from the linear solenoid valve 80 is input to the first assist chamber 33a of the first regulator valve 30 through the relay valve 50 and the assist oil passage 41, the line pressure of the first regulator valve 30 can be controlled. become.

(Operation 2-2)
When the on / off solenoid valve 60 is energized, the control hydraulic pressure (L / U pressure) controlled by the linear solenoid valve 80 and the control valve 70 is supplied to the lockup clutch 14 through the relay valve 50 and the lockup oil passage 54, and is locked. The up clutch 14 is engaged. Further, since the output pressure from the on / off solenoid valve 60 is input to the first assist chamber 33a of the first regulator valve 30 through the relay valve 50 and the assist oil passage 41, the line pressure PL is maintained at the maximum state.

  When the ON / OFF solenoid valve 60 is turned ON (failed while being energized), if the linear solenoid valve 80 is energized, the lockup clutch 14 is disengaged, and if the linear solenoid valve 80 is deenergized. The lockup clutch 14 is engaged.

  Further, when the on / off solenoid valve 60 is in an OFF failure (failure in a non-energized state), the lock-up clutch 14 is disengaged regardless of whether the linear solenoid valve 80 is energized or de-energized.

  Further, when the linear solenoid valve 80 is in an ON failure, the control hydraulic pressure (L / U pressure) is not output, so that the lockup clutch 14 is disengaged.

  Further, when the linear solenoid valve 80 fails, the lockup clutch 14 is engaged when the on / off solenoid valve 60 is energized, and the lockup clutch 14 is not engaged when the on / off solenoid valve 60 is deenergized. It becomes.

  According to the second embodiment, the linear solenoid valve used for controlling the first regulator valve 30 and the linear solenoid valve used for controlling the lockup clutch 14 can be shared, and the cost of the apparatus can be reduced. Further, as in the first embodiment, the lock-up clutch 14 can be disengaged regardless of which of the on-off solenoid valve 60 and the linear solenoid valve 80 fails, and the engine stall can be prevented. .

  In the configuration of the second embodiment, when the on / off solenoid valve 60 is replaced with a valve that can output an intermediate pressure such as a duty solenoid, the accuracy is improved by dividing the relay valve 50 into a switching region and a pressure regulating region based on the duty. However, it is possible to control the line pressure while adjusting the hydraulic pressure supplied to the lockup clutch 14.

(Embodiment 3)
A hydraulic control device for an automatic transmission according to Embodiment 3 of the present invention will be described with reference to the drawings. FIG. 3 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to the third embodiment of the present invention.

  In the hydraulic control device for an automatic transmission according to the third embodiment, the second regulator valve 90 and the cooler 100 are associated with the relay valve 50. Other configurations are the same as those in the first embodiment.

  The hydraulic control device 1 for an automatic transmission includes a torque converter 10, an oil pump 20, a first regulator valve 30, an accumulator 40, a relay valve 50, an on / off solenoid valve 60, a control valve 70, and a linear solenoid valve. 80, a second regulator valve 90, a cooler 100, and a bypass valve 110. The torque converter 10, the oil pump 20, the first regulator valve 30, the accumulator 40, the on / off solenoid valve 60, the control valve 70, and the linear solenoid valve 80 are the same as those in the first embodiment.

  The relay valve 50 is a lock-up relay valve that switches the oil path to the lock-up oil path 54 that communicates with the lock-up clutch 14, and has a function of switching the oil path to the assist oil path 41 that communicates with the first assist chamber 33a. Furthermore, it has a function of switching the oil path to the oil path 55 that communicates with the outlet of the torque converter 10 via the second regulator valve 90 and a function of switching the oil path to the oil path 58 that communicates with the cooler 100. The relay valve 50 includes a spool 51, a spring 52, and a hydraulic chamber 53. The spool 51 is slidably inserted in a valve body (not shown). The spring 52 biases the spool 51 toward the hydraulic chamber 53 side. In the hydraulic chamber 53, when the on / off solenoid valve 60 is not energized, the control oil pressure from the on / off solenoid valve 60 is introduced to move the spool 51 toward the spring 52, and when the on / off solenoid valve 60 is energized, the control oil pressure is turned on / off. The spool 51 is discharged by the solenoid valve 60 and moved to the hydraulic chamber 53 side. The relay valve 50 communicates the control valve 70 and the lockup clutch 14 when the on / off solenoid valve 60 is energized, and communicates the discharge port EX and the lockup clutch 14 when the on / off solenoid valve 60 is deenergized. The relay valve 50 communicates a modulator valve (not shown) that outputs a modulator pressure Pm when the on / off solenoid valve 60 is energized with the first assist chamber 33a of the first regulator valve 30 so that the on / off solenoid valve 60 is in communication. When the power is not energized, the linear solenoid valve 80 and the first assist chamber 33a of the first regulator valve 30 are communicated. The relay valve 50 communicates the oil passage 55 and the discharge port EX when the on / off solenoid valve 60 is energized, and communicates the oil passage 55 and the oil passage 58 when the on / off solenoid valve 60 is not energized. The relay valve 50 communicates the oil passage 56 and the oil passage 57 when the on / off solenoid valve 60 is energized, and shuts off the oil passage 56 and the oil passage 57 when the on / off solenoid valve 60 is not energized. The oil passage 56 and the oil passage 57 communicate with each other through the oil passage 58 via the relay valve 50.

  The second regulator valve 90 is a valve that regulates the hydraulic oil that enters and exits the pump 11, the turbine 12, and the stator 13 of the torque converter 10. The second regulator valve 90 outputs the hydraulic pressure (fifth hydraulic pressure) supplied from the first regulator valve 30 to the hydraulic pressure (sixth hydraulic pressure) pump 11, and the excess hydraulic pressure is output to the oil pan of the oil pump 20. Return to (not shown). The second regulator valve 90 regulates the hydraulic pressure (fourth hydraulic pressure) output from the turbine 12 and outputs it to the relay valve 50 via the oil passage 55. The second regulator valve 90 includes a spool 91 and a spring 92. The spool 91 is slidably fitted in a valve body (not shown) and is pushed toward the spring 92 by the hydraulic pressure supplied from the relay valve 50 to the hydraulic chamber 93 through the oil passage 56. The spring 92 biases the spool 91 toward the hydraulic chamber 93. The output pressure of the second regulator valve 90 is always input to the inlet of the torque converter 10. The land balance of the spool 91 in the hydraulic chamber 93 can be made smaller than the land diameter of other portions, or a pressure difference can be provided to change the pressure balance.

  The cooler 100 cools the hydraulic oil that has come out of the torque converter 10. The cooler 100 receives hydraulic oil input from the turbine 12 of the torque converter 10 via the second regulator valve 90, the oil passage 55, the relay valve 50 (when the on / off solenoid valve 60 is not energized), and the oil passage 58. It cools and outputs the cooled hydraulic fluid toward the lubrication system LUB.

  The bypass valve 110 is a valve that discharges excessive hydraulic pressure when excessive hydraulic pressure is applied to the oil passage 58.

  Next, the operation of the hydraulic control device for an automatic transmission according to the third embodiment of the present invention will be described.

(Operation 3-1)
When the on / off solenoid valve 60 is not energized, that is, when the lock-up clutch 14 is not engaged (see operation 1-1 of the first embodiment), the outlet of the torque converter 10 is the second regulator valve 90, the oil passage 55, the relay valve 50 and the oil passage 58 communicate with the cooler 100, so that the hydraulic oil flowing out of the torque converter 10 is cooled by the cooler 100. Here, when the lock-up clutch 14 is in the non-engaged state, the hydraulic oil generates heat due to the creep of the torque converter 10, so the hydraulic oil is cooled. Thereby, an appropriate lubricating flow rate can be ensured according to the load of the cooler 100.

(Operation 3-2)
When the on / off solenoid valve 60 is energized, that is, when the lock-up clutch 14 is engaged (see operation 1-2 in the first embodiment), the outlet of the torque converter 10 includes the second regulator valve 90, the oil passage 55, In addition, since the exhaust port EX communicates with the discharge port EX through the relay valve 50, the hydraulic oil flowing out from the torque converter 10 is discharged. Here, when the lock-up clutch 14 is in the engaged state, the torque converter 10 does not creep, so there is almost no heat generation of the hydraulic oil, and the hydraulic oil is discharged without cooling. Further, the hydraulic pressure (secondary pressure) output from the first regulator valve 30 to the second regulator valve 90 is an oil passage 57 branched from an oil passage leading from the first regulator valve 30 to the second regulator valve 90, and the relay valve 50. And the oil passage 56, the second regulator valve 90 reduces the input secondary pressure to the inlet of the torque converter 10 and outputs it to the inlet of the torque converter 10. It will be.

  In the third embodiment, the second regulator valve 90 and the cooler 100 are associated with the relay valve 50 based on the first embodiment. However, as shown in FIG. The cooler 100 can also be associated with the relay valve 50.

1 is a partial hydraulic circuit diagram schematically showing the configuration of a hydraulic control device for an automatic transmission according to Embodiment 1 of the present invention. FIG. 5 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to a second embodiment of the present invention. FIG. 6 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to a third embodiment of the present invention. FIG. 9 is a partial hydraulic circuit diagram schematically showing a configuration of a hydraulic control device for an automatic transmission according to a fourth embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hydraulic control apparatus 10 Torque converter 11 Pump 12 Turbine 13 Stator 14 Lockup clutch 20 Oil pump 30 1st regulator valve 31 Spool 31a Feedback chamber 32 Spring 33 1st assist valve 33a 1st assist chamber 34 2nd assist valve 34a 2nd Assist chamber 40 Accumulator 41 Assist oil passage 50 Relay valve 51 Spool 52 Spring 53 Hydraulic chamber 54 Lock-up oil passage 55, 56, 57, 58 Oil passage 60 On-off solenoid valve 70 Control valve 71 Spool 72 Spring 73 Hydraulic chamber 74 Feedback chamber 80 Linear solenoid valve 90 Second regulator valve 91 Spool 92 Spring 93 Hydraulic chamber 100 Cooler 110 Bypass valve

Claims (3)

A hydraulic control device for an automatic transmission including a torque converter having a lock-up clutch,
A first regulator valve having an assist chamber that adjusts the line pressure supplied from the oil pump in accordance with the position of the spool and assists the biasing of the spring against the spool from the spring receiving side when the hydraulic pressure is input;
A relay valve that switches an oil passage leading to the lock-up clutch according to the position of the spool;
An on-off solenoid valve for introducing the line pressure, outputting an output pressure according to the energized state, and switching the position of the spool of the relay valve;
A control valve that generates a first hydraulic pressure from the line pressure according to the position of the spool;
A linear solenoid valve that introduces a modulator pressure, outputs a second hydraulic pressure in accordance with an energization amount, and controls the position of the spool of the control valve;
With
The relay valve is configured to switch an oil passage leading to the assist chamber according to the position of the spool,
When the on / off solenoid valve is energized, the first hydraulic pressure output from the control valve is supplied to the lockup clutch through the relay valve, and the modulator pressure is supplied to the assist chamber through the relay valve. ,
When the on / off solenoid valve is in a non-energized state, the first hydraulic pressure output from the control valve is disconnected from the lock-up clutch by the relay valve and the first hydraulic pressure output from the linear solenoid valve. 2. A hydraulic control apparatus for an automatic transmission, wherein two hydraulic pressures are supplied to the assist chamber through the relay valve. A hydraulic control device for an automatic transmission including a torque converter having a lock-up clutch,
A first regulator valve having an assist chamber that adjusts the line pressure supplied from the oil pump in accordance with the position of the spool and assists the biasing of the spring against the spool from the spring receiving side when the hydraulic pressure is input;
A relay valve that switches an oil passage leading to the lock-up clutch according to the position of the spool;
An on / off solenoid valve that introduces a modulator pressure, outputs a third hydraulic pressure according to an energized state, and switches a position of the spool of the relay valve;
A control valve that generates a first hydraulic pressure from the line pressure according to the position of the spool;
A linear solenoid valve that introduces a modulator pressure, outputs a second hydraulic pressure in accordance with an energization amount, and controls the position of the spool of the control valve;
With
The relay valve is configured to switch an oil passage leading to the assist chamber according to the position of the spool,
When the on / off solenoid valve is energized, the first hydraulic pressure output from the control valve is supplied to the lockup clutch through the relay valve, and the third hydraulic pressure output from the on / off solenoid valve is Supplied to the assist chamber through the relay valve;
When the on / off solenoid valve is in a non-energized state, the first hydraulic pressure output from the control valve is disconnected from the lock-up clutch by the relay valve and the first hydraulic pressure output from the linear solenoid valve. 2. A hydraulic control apparatus for an automatic transmission, wherein two hydraulic pressures are supplied to the assist chamber through the relay valve. According to the position of the spool, the line pressure supplied from the first regulator valve is adjusted and output toward the inlet of the torque converter, and the fourth hydraulic pressure that flows out of the outlet of the torque converter is adjusted. A second regulator valve having a hydraulic chamber that presses and outputs toward the relay valve, and is pressed in a direction opposite to the biasing direction of the spring against the spool when hydraulic pressure is input;
A cooler for cooling the hydraulic oil;
With
The relay valve is configured to switch an oil passage leading to the first regulator valve, the second regulator valve, and the cooler according to the position of the spool.
When the on-off solenoid valve is energized and the lock-up clutch is engaged, the fourth hydraulic pressure that has flowed out from the outlet of the torque converter is discharged from the discharge port through the second regulator valve and the relay valve; and The fifth hydraulic pressure output as a part of the line pressure from the first regulator valve is supplied to the hydraulic chamber of the second regulator valve through the relay valve, so that the torque converter The sixth hydraulic pressure output toward the inflow port is kept low,
When the on / off solenoid valve is in a non-energized state and the lock-up clutch is in a non-engaged state, the fourth hydraulic pressure that flows out from the outlet of the torque converter is supplied to the cooler through the second regulator valve and the relay valve. 3. The hydraulic control device for an automatic transmission according to claim 1, wherein the hydraulic control device is configured as described above.

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