JP2007032702A - Hydraulic control device for automatic transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hydraulic control device for an automatic transmission capable of securing vehicle traveling even when an electric system is failed, without complicating a hydraulic circuit and hydraulic control. <P>SOLUTION: This hydraulic control device comprises a plurality of shift actuators 41-44 setting transmission gear train transmitting power from the plurality of transmission gear trains, neutral switch valves 51-54, and a manual valve for selectively switching a shift lever S. When the manual valve is located at a P-position, the neutral switching valves 51-54 are switched from a stationary operation state to a neutral mode, and the shift actuators 41-44 are respectively placed at a neutral position, and in a D-position or a R-position, the specific neutral switch valve 52 is switched to a limp home mode, and hydraulic pressure is supplied to the shift actuator 42 to set the transmission gear train transmitting power, by the shift actuator. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a hydraulic control device for an automatic transmission mounted on an automobile, and more particularly to a hydraulic control device effective when applied to an automatic transmission having a plurality of transmission gear trains.

  A manual transmission (MT) that performs a shifting operation by a driver's manual operation is mounted with an input shaft that is connected to an engine and on which a plurality of driving gears are mounted, and a plurality of driven gears that are paired with these driving gears. The output shaft is arranged in parallel, and a plurality of transmission gear trains are formed by a drive gear and a driven gear that mesh with each other between the input shaft and the output shaft. In this MT, after releasing the engagement of the clutch at the time of shifting, the switching mechanism such as a synchromesh mechanism for switching to a transmission gear train that transmits power from a plurality of transmission gear trains is manually switched, and the clutch is engaged again. As a result, a shifting operation is performed.

  In addition, when an operation such as a switching mechanism for switching a plurality of transmission gear trains formed by the drive gear and the driven gear and a clutch operation are operated by an actuator such as a hydraulic mechanism, an automatic operation based on the MT configuration is performed. It can be a transmission. Such an automatic transmission (AMT) having a plurality of transmission gear trains can be reduced in weight by reducing the number of parts compared to a normal automatic transmission (AT) having a planetary gear or the like in an automatic transmission mechanism. In addition, there are advantages such as excellent transmission efficiency of the drive system.

  Here, in the AMT type automatic transmission, when an electrical failure occurs during vehicle travel, if the select lever is selected from the reverse range or the neutral range to the drive range, a predetermined transmission gear train is set by the bypass clutch. After the input shaft and the output shaft are engaged, and the shift actuator is in the neutral position, hydraulic pressure is supplied to the input clutch via the neutral position detection valve that detects the neutral position, and the input clutch is engaged. A hydraulic control device is known (see, for example, Patent Document 1).

JP 2002-307984 A

  According to Patent Document 1, forward / backward travel is possible by operating the select lever even if an electrical failure occurs, and the vehicle can be driven even when an electrical failure occurs.

  However, in order to supply hydraulic pressure to the shift actuator and maintain and stop the neutral position when the electric system fails, the hydraulic circuit becomes complicated and complicated hydraulic control is required.

  Accordingly, an object of the present invention made in view of the above point is to provide a hydraulic control device for an automatic transmission that can ensure vehicle travel even if an electrical system failure occurs without causing a complicated hydraulic circuit or hydraulic control. It is in.

  The invention of the hydraulic control device for an automatic transmission according to claim 1 that achieves the above object includes: an input shaft that selectively transmits power from an engine by engaging and disengaging an input clutch; and an output that transmits power to wheels. In a hydraulic control device for an automatic transmission comprising a shaft, and a plurality of transmission gear trains formed by a plurality of drive gears provided on the input shaft and a driven gear provided on the output shaft and meshing with the drive gear A plurality of shift actuators for selectively setting a transmission gear train for transmitting power from the input shaft to the output shaft from the plurality of transmission gear trains; and neutral switching valves respectively disposed corresponding to the shift actuators; P position depending on selection of shift lever parking range, neutral range, drive range and reverse range in case of electrical failure A manual valve that can be switched to an N position, a D position, and an R position. When the manual valve is in an N position or a P position, each neutral switching valve is switched from a steady operation state to a neutral state, and each shift actuator is in a neutral position. The hydraulic pressure is supplied to each shift actuator so that a specific neutral switching valve of the plurality of neutral switching valves is switched to the limp home state when the manual valve is in the D position or the R position. A hydraulic pressure is supplied to the shift actuator so as to set a transmission gear train to be transmitted.

  The invention of the hydraulic control device for an automatic transmission according to claim 2 that achieves the above object includes: an input shaft that selectively transmits power from an engine by engaging and disengaging an input clutch; and an output that transmits power to wheels. In a hydraulic control device for an automatic transmission comprising a shaft, and a plurality of transmission gear trains formed by a plurality of drive gears provided on the input shaft and a driven gear provided on the output shaft and meshing with the drive gear , A specific shift actuator that sets a transmission gear train for transmitting power from the input shaft to the output shaft among the plurality of transmission gear trains as a specific forward transmission gear train or a reverse transmission gear train, and a transmission for transmitting the power. A general shift actuator that sets the gear train to another transmission gear train, and the corresponding specific shift actuator and general shift actuator Specific neutral switching valve and general neutral switching valve, and P position, N position, D position and R according to the selection of the parking range, neutral range, drive range and reverse range of the shift lever at the time of failure of the electric system A manual valve that can be switched to a position state, and a limp home switching valve that switches the hydraulic circuit from a steady operation circuit to a limp home circuit in the P position state of the shift lever. The hydraulic circuit is switched from a steady operation circuit to a limp home circuit by a limp home switching valve, and the specific neutral switching valve is set to a specific position so that the specific shift actuator is in a neutral position when the manual valve is in the N position or P position. Schiff Actuator hydraulic pressure is supplied, and each general manual valve supplies hydraulic pressure to the general shift actuator so that the general shift actuator is in a neutral position. The neutral switching valve is characterized in that the transmission gear train to which power is transmitted by the specific shift actuator is switched to the specific forward transmission gear train or the reverse transmission gear train.

  According to a third aspect of the present invention, in the hydraulic control device for an automatic transmission according to the first or second aspect, each of the shift actuators includes a first cylinder portion and a second cylinder portion that are coaxially opposed to each other, and the first cylinder portion. The first cylinder is slidably mounted in one cylinder and cooperates with the first cylinder to form a first shift hydraulic chamber and a first neutral hydraulic chamber, and the second cylinder is slidably mounted. A spool valve shaft in which a second spool portion that forms a second shift hydraulic chamber and a second neutral hydraulic chamber in cooperation with the second cylinder is integrally formed, and a first limp home pressure that opens to the first cylinder portion An introduction port, a first communication port that communicates with the first neutral hydraulic chamber, a second limp home pressure introduction port that opens to the second cylinder portion, and a second communication port that communicates with the second neutral hydraulic chamber, The spool valve shaft is moved to the second shift position by the control hydraulic pressure supplied to the first shift hydraulic chamber, the spool valve shaft is moved to the first shift position by the control hydraulic pressure supplied to the second shift hydraulic chamber, and The limp home pressure introduced from the first limp home pressure introduction port when the spool valve shaft is in the first shift position can be introduced into the first neutral hydraulic chamber via the first communication port, and the second limp home pressure introduction port is provided. The limp home pressure introduced from the second limp home pressure introduction port when the spool valve shaft is closed by the second spool portion and in the second shift position can be introduced into the second neutral hydraulic chamber via the second communication port. The first limp home pressure introduction port is closed by the first spool portion, and the first limp home pressure introduction port is in the neutral position when the spool valve shaft is in the neutral position. 1 is closed by the spool portion and the second air bypass pressure introduction port, characterized in that it is closed by the second spool section.

  According to the first aspect of the present invention, the neutral switching valve is switched from the steady operation state to the neutral state by selecting the parking lever or the neutral range of the shift lever at the time of failure of the electric system, and each shift actuator is in the neutral position. When the drive range or reverse range of the shift lever is selected while the shift actuator is maintained at the neutral position, a specific neutral switching valve is switched to the limp home state, and a transmission gear train for transmitting power by the shift actuator is set. . In addition, the hydraulic control of the neutral switching valve and the shift actuator is performed according to the manual valve that is switched by operating the shift lever, and the vehicle can be ensured when the electric system fails without complicating the hydraulic circuit and hydraulic control.

  According to the second aspect of the present invention, when the parking range is selected by the shift lever at the time of failure of the electric system, the hydraulic circuit is switched from the steady operation circuit to the limp home circuit by the limp home switching valve, and is switched to the limp home circuit and shifted. By selecting the parking range or neutral range of the lever, the specific neutral switching valve is switched from the steady operation state to the neutral state, and the specific shift actuator is set to the neutral position. Similarly, the general neutral switching valve is switched from the steady operation state to the neutral state. Instead, the general shift actuator is also in the neutral position. When the drive range is selected by operating the shift lever while each shift actuator is maintained at the neutral position, the specific neutral switching valve is switched to the limp home state, and the transmission gear train that transmits power by the specific shift actuator moves forward. The transmission gear train is set. On the other hand, when the reverse range is selected by operating the shift lever, the specific neutral switching valve is switched to the limp home state, and the transmission gear train for transmitting power by the specific shift actuator is set as the reverse transmission gear train.

  The hydraulic control of the limp home switching valve, the specific neutral switching valve, the specific shift actuator, the general neutral switching valve, and the general shift actuator is performed according to the manual valve that is switched by operating the shift lever. It is possible to ensure forward traveling and backward traveling of the vehicle at the time of failure of the electric system without causing complication.

  According to the invention of claim 3, the spool valve shaft is moved to the second shift position by the control hydraulic pressure supplied to the first shift hydraulic chamber, and the spool valve shaft is moved by the control hydraulic pressure supplied to the second shift hydraulic chamber. A shift gear train that moves to the first shift position and transmits power is set.

  When the spool valve shaft introduces limp pressure from the first limp home pressure introduction port at the first shift position, the limp pressure is introduced into the first neutral hydraulic chamber via the first communication port, and the spool valve shaft is brought to the neutral position. The first limp home pressure introduction port is closed by the first spool portion in the neutral position, and the spool valve shaft is held in the neutral position. On the other hand, when the limp pressure is introduced from the second limp home pressure introduction port at the second shift position, the limp pressure is introduced into the second neutral hydraulic chamber via the second communication port, and the spool valve shaft moves to the neutral position. The second limp home pressure introduction port is closed by the second spool portion in the neutral position, and the spool valve shaft is held in the neutral position.

(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is a skeleton diagram showing an automatic transmission having a hydraulic control apparatus according to an embodiment of the present invention. In this automatic transmission, a hollow first input shaft 11, a second input shaft 12 penetrating through the first input shaft 11, an output shaft 13, and an idler gear shaft 14 are arranged in parallel so as to be placed in a transmission case (not shown). It has been incorporated. Power from the engine E is transmitted to the first input shaft 11 and the second input shaft 12 via the first input clutch 15 and the second input clutch 16, respectively.

  Further, the shift output from the output shaft 13 is transmitted to the drive shaft 18 via the reduction gear 17, and is transmitted from the drive shaft 18 to the left and right drive wheels via the differential device 19.

  On the first input shaft 11, drive gears 26a, 24a, and 22a for 6th speed, 4th speed, and 2nd speed are integrally mounted in order from the first input clutch 15 side. Drive gears 23a, 25a, and 21a for the third speed, the fifth speed, and the first speed are integrally attached to the second input shaft 12 in order from the second input clutch 16 side.

  On the other hand, on the output shaft 13, driven gears 26b, 24b for 6th speed, 4th speed, 2nd speed, 3rd speed, 5th speed, 1st speed, which are always meshed with the drive gears 26a, 24a, 22a, 23a, 25a, 21a, respectively. 22b, 23b, 25b, and 21b are rotatably mounted. Each of the drive gear and the driven gear meshing with each other forms a forward transmission gear train, and when a transmission gear train that transmits power is selected from the plurality of transmission gear trains, the transmission gear train causes the first to sixth gears. A forward gear for high speed is formed.

  Further, a reverse drive gear 27 a is integrally mounted on the second input shaft 12, a driven gear 27 b is rotatably mounted on the output shaft 13, and the drive gear 27 a and the driven gear 27 b are mounted on the idler shaft 14. The reverse transmission gear train is formed by always meshing with the idler gear 27c.

  The output shaft 13 includes a first switching mechanism 31 that selectively switches a transmission gear train for transmitting power between a sixth speed transmission gear train and a fourth speed transmission gear train, and a specific transmission gear train. A second switching mechanism 32 that selectively switches between the second-speed transmission gear train and the reverse transmission gear train, and a third switching that selectively switches between the third speed and the fifth speed, which are general transmission gear trains. A mechanism 33 and a fourth switching mechanism 34 for selectively switching a transmission gear train for transmitting power to a first-speed transmission gear train serving as a general transmission gear train are disposed. These switching mechanisms 31 to 34 are configured by a synchromesh mechanism. It is configured.

  The first switching mechanism 31 has a synchro hub 31a that is disposed between the driven gears 26b and 24b and is fixed to the output shaft 13, and a synchro sleeve 31b that always meshes with the synchro hub 31a. When meshed with the integrally formed spline 26d, the transmission gear train for transmitting power is set to the sixth speed, and when meshed with the spline 24d integrally formed with the driven gear 24b, it is set to the fourth speed.

  Similarly, the second switching mechanism 32 has a synchro hub 32a fixed to the output shaft 13 between the driven gears 22b and 27b, and a synchro sleeve 32b that always meshes with this, and the synchro sleeve 32b is integrated with the driven gear 22b. When meshed with the formed spline 22d, the second speed is set, and when meshed with the spline 27d formed integrally with the driven gear 27b, the reverse gear is set. Further, the third switching mechanism 33 has a synchro hub 33a fixed to the output shaft 13 between the driven gears 23b and 25b, and a synchro sleeve 33b that always meshes with the synchro hub 33a. The synchro sleeve 33b is integrally formed with the driven gear 23b. When meshed with the spline 23d, the third speed is set, and when meshed with the spline 25d integrally formed with the driven gear 25b, the fifth speed is set. The fourth switching mechanism 33 includes a synchro hub 34a fixed to the output shaft 13 between the driven gears 25b and 21b, and a synchro sleeve 34b that always meshes with the synchro hub 34b. The synchro sleeve 34b is integrally formed with the driven gear 21b. When meshed with the spline 21d, the transmission gear train for transmitting power is set to the first speed.

  A first shift actuator 41 that is a general shift actuator that sets a transmission gear train for transmitting power to either 6th speed or 4th speed, and a second that is a specific shift actuator that is set to either 2nd speed or reverse speed. It has a shift actuator 42, a third shift actuator 43 that is a general shift actuator set to either the third speed or the fifth speed, and a fourth shift actuator 44 that is a general shift actuator set to the first speed. Yes.

  The first shift actuator 41 includes a 6th speed position where the synchro sleeve 31b of the first switching mechanism 31 is engaged with the spline 26d and set to 6th speed, a 4th speed position where the synchro sleeve 31b is engaged with the spline 24d and set to 4th speed, It is moved to a neutral position that does not mesh with the splines 26d and 24d.

  Similarly, the second shift actuator 42 has a second speed position for setting the second speed by meshing the sync sleeve 32b of the second switching mechanism 32 with the spline 22d, and a reverse position for setting the reverse gear by meshing with the spline 27d. , And move to a neutral position that does not mesh with the splines 22d and 27d. The third shift actuator 43 includes a third speed position where the sync sleeve 33b of the third switching mechanism 33 is engaged with the spline 23d to set the third speed, a fifth speed position which is engaged with the spline 25d and set to the fifth speed, and the spline. It is moved to a neutral position that does not mesh with 23d and 25d. The fourth shift actuator 44 moves the sync sleeve 34b of the fourth switching mechanism 34 to the spline 21d to the first speed position where it is set to the first speed, and moves to the neutral position where it does not mesh with the spline 21d.

  The automatic transmission having such a configuration is controlled by a shift control system shown in FIG. The electronic control unit (ECU) 49 receives various signals such as the engine speed Ne, the throttle opening θ, the vehicle speed v, the select position SL, and the selected gear stage PG. The ECU 49 specifies a gear position according to the current traveling state from these signals, and outputs an appropriate control signal to the hydraulic control device 50. The hydraulic control unit 50 includes a hydraulic pump, various hydraulic control valves, and the like, and supplies control pressure to the first input clutch 15 and the second input clutch 16 in accordance with a control signal from the ECU 49, and the first to first clutches. 4 is supplied to each of the four shift actuators 41-44.

  For example, when a 6th, 4th, or 2nd speed gear train is selected and the first input clutch 14 is engaged, a 6th, 4th, or 2nd speed is set, and the 3rd, 5th, or 1st speed is set. When the second speed change gear train is selected and the second input clutch 15 is engaged, the third, fifth, or first speed gear stage is set, and the shift output is transmitted from the output shaft 13 to the drive shaft 18 via the reduction gear 17. Then, it is transmitted from the drive shaft 18 to the left and right drive wheels via the differential device 19.

  Further, when the reverse gear train is selected and the second input clutch 16 is engaged, the reverse gear is set, and the shift output is transmitted from the output shaft 13 to the drive shaft 18 via the reduction gear 17. To the left and right drive wheels via the differential device 19.

  FIGS. 3 and 4 are hydraulic circuit diagrams of the hydraulic control device 50 of the automatic transmission, respectively. In these hydraulic circuit diagrams of FIGS. 3 and 4, they are connected at corresponding portions a to k.

  The hydraulic control device 50 includes a hydraulic pressure pump that is driven by an engine or an electric motor, and a hydraulic pressure supply unit P that includes a pressure adjusting device that adjusts the hydraulic pressure to a predetermined line pressure, first to fourth shift actuators 41 to 44, From the first to fourth neutral switching valves 51 to 54, the first and second clutch pressure regulating valves 55 and 56, the manual valve 57, the limp home circuit switching valve 58, the limp home circuit switching valve stopper device 59 and the electromagnetic valve. Each control valve 41Va-41Vd, 42Va-42Vd, 43Va-43Vd, 44Va-44Vd, 45Va, 45Vb46Va, 46Vb is provided, and the line pressure from the hydraulic pressure supply part P is fed to each part via the line pressure oil path PL. Is done.

  The first shift actuator 41 includes a first cylinder part 41A and a second cylinder part 41B provided in the transmission case so as to face each other in parallel with the extending direction of the output shaft 13, as shown in enlarged views in FIGS. And a spool valve shaft 41C in which a first spool portion 41D slidably mounted in the first cylinder portion 41A and a second spool portion 41E slidably mounted in the second cylinder 41B are integrally formed. The spool valve shaft 41C is provided with a shift fork 41S (see FIG. 1) whose tip engages with a groove formed on the outer periphery of the sync sleeve 31b of the first switching mechanism 31.

  The first cylinder part 41A and the second cylinder part 41B have the same shape and are coaxially opposed to each other. The first cylinder part 41A has a small diameter part 41Aa and a large diameter part 41Ab on the top end side away from the second cylinder part 41B. The second cylinder portion 41B is continuously formed with a small-diameter portion 41Ba and a large-diameter portion 41Bb on the top end side via the step portion 41Bc.

  A control pressure supply port 41Ad communicating with the inside of the small diameter portion 41Aa is formed at the top end of the second cylinder portion 41A, and the first limp home pressure introduction port 41Ae, the first communication port 41Af, and the large diameter portion 41Ab in this order from the step portion 41Ac side. A first drain port 41Ag is formed, and the first communication port 41Af communicates with a port 41Ah formed in the step portion 41Ac via an oil passage 41Ai. Similarly, a control pressure supply port 41Bd communicating with the inside of the small diameter portion 41Ba is formed at the top end of the second cylinder portion 41B, and the second limp home pressure introduction port 41Be and the second communication port are sequentially formed on the large diameter portion 41Bb from the step portion 41Bc side. 41Bf and the second drain port 41Bg are formed, and the second communication port 41Bf communicates with the port 41Bh formed in the step portion 41Bc through the oil passage 41Bi.

  On the other hand, the first spool portion 41D of the spool valve shaft 41C has a small diameter portion 41Da slidably mounted on the small diameter portion 41Aa of the first cylinder 41A and a large diameter portion 41Db slidably mounted on the large diameter portion 41Ab. Is formed through the step portion 41Dc, and an annular groove 41Dd is formed on the outer periphery of the large diameter portion 41Db. Here, the inner diameter R2 of the groove 41Dd is set larger than the outer diameter R1 of the small diameter portion 41Da (R1 <R2). Similarly, the second spool portion 41E includes a small diameter portion 41Ea slidably mounted on the small diameter portion 41Ba of the second cylinder portion 41B and a large diameter portion 41Eb slidably mounted on the large diameter portion 41Bb. An annular groove 41Ed is formed in the large diameter portion 41Eb. The inner diameter R2 of the groove 41Ed is set to be larger (R1 <R2) than the outer diameter R1 of the small diameter portion 41Ea.

  The spool valve shaft 41C has a first speed position in which the movement is restricted by the step 41Dc of the first spool portion 41D coming into contact with the step 41Ac of the first cylinder portion 41A, as indicated by a dashed line in FIG. As shown by the two-dot chain line, the step 41Ec of the second spool 41E abuts on the step 41Bc of the second cylinder 41B and the movement is restricted, and the neutral position shown by the solid line. It can be moved in the axial direction. At this first speed change position, the shift fork 41S provided on the spool valve shaft 41C sets the synchro sleeve 31b to the sixth speed that engages with the spline 26d formed integrally with the driven gear 26b. At the second speed change position, the synchro sleeve 31b The fourth speed is set to mesh with the spline 24d on the driven gear 24b side, and the synchro sleeve 31b is set to the neutral position where it does not mesh with the splines 26d and 24d in the neutral position.

  As shown in FIG. 6A, the spool valve shaft 41C closes the first drain hole 41Ag by the large diameter portion 41Db of the first spool portion 41D as shown in FIG. 6A, and the first limp home pressure introduction port 41Ae and the groove 41Dd While the first communication port 41Af is opened, the large diameter portion 41Eb of the second spool portion 41E closes the second limp home pressure introduction port 41Be and opens the second communication port 41Bf and the second drain port 41Bg by the groove 41Ed.

  Similarly, when the spool valve shaft 41C is in the second speed change position, the second drain hole 41Bg is closed by the large diameter portion 41Eb of the second spool portion 41E, and the second limp home pressure introduction port 41Be and the second communication port 41Bf are closed by the groove 41Ed. On the other hand, the large diameter portion 41Db of the first spool portion 41D closes the first limp home pressure introduction port 41Ae and opens the first communication port 41Af and the first drain port 41Ag by the groove 41Dd.

  In the neutral position, as shown in FIG. 6B, the first limp home pressure introduction port 41Ae and the first drain port 41Ag are closed by the large diameter portion 41Db of the first spool portion 41D, and similarly the large diameter of the second spool 41E. The portion 41Eb is configured to close the second limp home pressure introduction port 41Be.

  When the control hydraulic pressure is introduced into the second shift hydraulic pressure chamber 41-2 from the control pressure supply port 41Bd of the second cylinder 41B, for example, when the spool valve shaft 41C is in the neutral position, the first actuator 41 configured in this way is The control pressure acts on the end face 41Es of the small diameter portion 41Ea of the two spool portion 41E, and the neutral position moves to the first shift position indicated by the one-dot chain line. On the other hand, when the control oil pressure is introduced from the control pressure supply port 41Ad of the first cylinder portion 41A to the first speed change hydraulic chamber 41-1, the control pressure acts on the end surface 41Ds of the small diameter portion 41Da of the first spool portion 41D, and the neutral position. To the second shift position indicated by the two-dot chain line.

  In addition, when the limp home pressure is introduced from the first limp home pressure introduction port 41Ae when the spool valve shaft 41C is in the first speed change position, the limp home pressure passes from the port 41Ah via the groove 41Dd and the oil passage 41Ai of the spool valve shaft 41C. The spool valve shaft 41C is introduced into the first neutral hydraulic chamber 41Dn and a control pressure acts on the step portion 41Dc to move toward the neutral position. In the neutral position, the first limp home pressure introduction port 41Ae and the first drain port 41Ag Is closed by the large-diameter portion 41D. When the first limp home pressure introduction port 41Ae and the first drain port 41Ag are closed, the difference between the outer diameter R1 of the small diameter portion which is the inner diameter of the first neutral hydraulic chamber 41Dn and the inner diameter R2 of the groove 41Dd is combined. The movement of the hydraulic oil sealed in the first neutral hydraulic chamber 41Dn, the groove 41Dd, and the oil passage 41Ai is prevented, and the spool valve shaft 41C stops at the neutral position and is maintained at the position.

  Similarly, when the limp home pressure is introduced from the second limp home pressure introduction port 41Bd when the spool valve shaft 41C is in the second speed change position, the limp home pressure is communicated via the groove 41Ed and the communication passage 41Bi of the large diameter portion 41E. The port 41Bf is introduced into the second neutral hydraulic chamber 41En and limp home pressure is applied to the step portion 41Ec to move the spool valve shaft 41C toward the neutral position. In the neutral position, the second limp home pressure introduction port 41Be has a large diameter portion. Closed by 41E and stopped and maintained in this position.

  The second shift actuator 42 has the same configuration as the first shift actuator 41. As shown in FIG. 3 and an enlarged view of the main part, as shown in FIG. 7, a first cylinder 42A in which a small diameter portion 42Aa and a large diameter portion 42Ab are continuously formed via a step portion 42Ac, and a small diameter portion 42Ba and a large diameter portion 42Bb are step portions. It has the 2nd cylinder part 42B formed continuously via 42Bc, and the spool shaft valve 42C. The spool valve shaft 42C is a first spool portion in which a small diameter portion 42Da and a large diameter portion 42Db are slidably mounted on the small diameter portion 42Aa and the large diameter portion 42Ab of the first cylinder portion 42A via a step portion 42Dc. 42D, a small diameter portion 42Ea slidably mounted in the small diameter portion 42Ba and the large diameter portion 42Bb of the second cylinder portion 42B, and a second spool portion 42E in which the large diameter portion 42Eb is formed through the step portion 42Ec. It is integrally formed. An annular groove 42Dd is formed on the outer periphery of the large diameter portion 42Db of the first spool portion 42D, and an annular groove 42Ed is formed on the large diameter portion 42Eb of the second spool portion 42E. The spool valve shaft 42C is provided with a shift fork 42S (see FIG. 1) whose tip engages with a groove formed on the outer periphery of the sync sleeve 32b of the second switching mechanism 32.

  For example, when the control hydraulic pressure is introduced from the control pressure supply port 42Ad of the first cylinder portion 42A to the first transmission hydraulic chamber 42-1 when the spool valve shaft 42C is in the neutral position, the control pressure is indicated by a two-dot chain line from the neutral position. When the control oil pressure is introduced into the second speed change hydraulic chamber 42-2 from the control pressure supply port 42Bd of the second speed cylinder 42B, the control pressure moves to the first speed position indicated by the one-dot chain line. .

  When the limp home pressure is introduced from the first limp home pressure supply port 42Ae when the spool valve shaft 42C is in the first shift position indicated by the alternate long and short dash line, the limp home pressure is changed into the groove 42Dd and the communication passage 42Ai of the first spool portion 42D. Through the first neutral hydraulic chamber 42Dn, the control pressure acts on the step portion 42Dc, the spool valve shaft 42C moves in the neutral position direction, and the first limp home pressure introduction port 42Ae and the first in the neutral position indicated by the solid line. The drain port 42Dg is closed by the large diameter portion 42D, and the spool valve shaft 42C is stopped and maintained in this position. Similarly, when the limp home pressure is introduced from the second limp home pressure introduction port 42Be when the spool valve shaft 42C is in the second shift position indicated by the two-dot chain line, the limp home pressure is changed to the grooves 42Ed and the second spool portion 42E. The limp home pressure is introduced into the second neutral hydraulic chamber 41En via the communication path 42Bi, the limp home pressure is applied to the step portion 42Ec, and the spool valve shaft 42C moves in the neutral position direction, and the second limp home pressure introduction port at the neutral position indicated by the solid line. 42Be and the second drain port 42Bg are closed by the large diameter portion 42E, and the spool valve shaft 42C is maintained in the neutral position.

  The configuration is the same as that of the third shift actuator 43 and the first shift actuator 41, and the small diameter portion 43Aa and the large diameter portion 43Ab are continuously formed via the step portion 43Ac as shown in FIG. The first cylinder portion 43A, the second cylinder portion 43B in which the small diameter portion 43Ba and the large diameter portion 43Bb are continuously formed via the step portion 43Bc, and the spool valve shaft 43C. The spool shaft valve 43C is a first spool portion in which a small diameter portion 43Da and a large diameter portion 43Db are slidably mounted in a small diameter portion 43Aa and a large diameter portion 43Ab of the first cylinder portion 43A via a step portion 43Dc. 43D, a small diameter portion 43Ba of the second cylinder portion 43B and a small diameter portion 43Ea slidably mounted in the large diameter portion 43Bb, and a second spool portion 43E in which the large diameter portion 43Eb is formed via the step portion 43Ec. The grooves 43Dd are formed in the large diameter portion 43Db, and the grooves 43Ed are formed in the large diameter portion 43Eb. The spool shaft valve 43C is provided with a shift fork 43S (see FIG. 1) whose tip engages with a groove formed on the outer periphery of the sync sleeve 33b of the third switching mechanism 33.

  For example, when the control shaft pressure is introduced into the second speed change hydraulic chamber 43-2 from the control pressure supply port 43Bd in the neutral position, the spool shaft valve 43C moves to the first speed change position indicated by a one-dot chain line by the control pressure. The supply port 43Ad moves to a second shift position indicated by a two-dot chain line for introducing control hydraulic pressure into the first shift hydraulic chamber 43-1. Further, when the spool valve shaft 43C is in the first speed change position, the limp home pressure introduced from the first limp home pressure introduction port 43Ae is introduced into the first neutral hydraulic chamber 43Dn via the groove 43Dd and the communication passage 43Ai of the first spool portion 43D. Then, the spool shaft valve 43C is moved in the neutral position direction by the limp home pressure, the first limp home pressure introduction port 43Ae is closed by the large diameter portion 43D at the neutral position, and the spool valve shaft 43C is stopped at the neutral position. In this position. Similarly, when the spool valve shaft 43C is in the second speed change position, the limp home pressure introduced from the second limp home pressure introduction port 43Be passes through the groove 43Ed and the communication passage 43Bi of the second spool portion 43E and the second neutral hydraulic chamber 43En. The spool shaft valve 43C moves in the neutral position direction, the second limp home pressure introduction port 43Be is closed by the large diameter portion 43E in the neutral position, and the spool valve shaft 43C is stopped and maintained at this position. .

  The configuration is the same as that of the fourth shift actuator 44 and the first shift actuator 41. As shown in FIG. 3 and the enlarged view of the main part, the small diameter portion 44Aa and the large diameter portion 44Ab are continuously formed via the step portion 44Ac. The first cylinder portion 44A, the small diameter portion 44Ba, and the large diameter portion 44Bb are continuously formed via the step portion 44Bc, and have a second cylinder portion 44B and a spool valve shaft 44C. The spool valve shaft 44C is a first spool portion in which a small diameter portion 44Da and a large diameter portion 44Db are slidably mounted in a small diameter portion 44Aa and a large diameter portion 44Ab of the first cylinder portion 44A via a step portion 44Dc. 44D and a second spool portion 44E in which a small-diameter portion 44Ea and a large-diameter portion 44Eb, which are slidably mounted in a small-diameter portion 44Ba and a large-diameter portion 44Bb of the cylinder 44B, are formed through a step portion 44Ec. ing. An annular groove 44Dd is formed in the large diameter portion 44Db of the first spool portion 44D, and an annular groove 44Ed is formed in the large diameter portion 44Eb of the second spool portion 44E. The spool valve shaft 44C is provided with a shift fork 44S (see FIG. 1) whose tip engages with a groove formed on the outer periphery of the synchronization sleeve 34b of the fourth switching mechanism 34.

  For example, when the control hydraulic pressure is introduced from the control pressure supply port 44Ad of the first cylinder 44A into the first shift hydraulic chamber 44-1 when the spool valve shaft 44C is in the neutral position, the second shift indicated by a two-dot chain line is generated by the control pressure. When the control oil pressure is introduced from the control pressure supply port 44Bd of the second cylinder portion 44B, the control pressure moves to the neutral position indicated by the solid line or the first shift position indicated by the alternate long and short dash line. In addition, when the limp home pressure is introduced from the second limp home pressure introduction port 44Be when the spool valve shaft 44C is in the 2-speed shift position, the limp home pressure is passed through the groove 44Ed and the communication passage 44Bi of the spool valve shaft 44C and the second neutral hydraulic pressure. Introduced into the chamber 44En, limp home pressure acts on the step portion 44Ec, the spool valve shaft 44C moves in the neutral position direction, and the second limp home pressure introduction port 44Be is closed by the large diameter portion 44E in the neutral position. The shaft 44C is stopped and held at the neutral position.

  On the other hand, the first neutral switching valve 51 includes a port 51a that communicates with the control pressure supply port 41Ad of the first shift actuator 41 via an oil passage 61a, as shown together with the first shift actuator 41 in FIGS. A port 51b communicating with the pressure supply port 41Bd via an oil passage 61b, a port 51c communicating with both the limp home pressure introduction ports 41Ae and 41Be via an oil passage 61c, and an oil passage 61d via a control valve 41Va The port 51d connected to the line pressure oil path PL, the port 51e connected to the line pressure oil path PL via the oil path 61e via the control valve 41Vb, and the N of the manual valve 57 described later via the oil path 61f. A port communicating to the port 51f communicating with the port 57a and an oil passage 61g branched from the oil passage 61f. Lot port 51g is provided. The port 51d is connected to the drain oil path DL via the oil path 61h branched from the oil path 61d and the control valve 41Vc, and the port 51e is drained via the oil path 61i branched from the oil path 61e and the control valve 41Vd. It is connected to the road DL.

  Further, the first neutral switching valve 51 has a spool valve shaft 51A that is operated by the pilot pressure from the pilot port 51g and the urging force of the spring 51s. Thus, the spool valve shaft 51A is maintained in the steady operation position, the ports 51a and 51d, the ports 51b and 51e are communicated, and the ports 51c and 51f are closed. On the other hand, when the pilot pressure is supplied, the spool valve shaft 51A is pushed to the neutral position against the biasing force of the spring 51s, the ports 51a, 51d, 51b, 51e are closed, and the ports 51c and 51f are communicated.

  As shown in FIGS. 3 and 7 together with the second shift actuator 42, the second neutral switching valve 52 includes a port 52a communicating with the control pressure supply port 42Bd of the second shift actuator 42 via an oil passage 62a, and a control pressure supply. A port 52b that communicates with the port 42Bd via the oil passage 62b, a port 52c that communicates with both the limp home pressure introduction ports 42Ae and 42Be via the oil passage 62c, and a line via the oil passage 62d that includes the control valve 42Va. The port 52d connected to the pressure oil passage PL, the port 52e connected to the line pressure oil passage PL via the oil passage 62e through the control valve 42Vb, and the D port 57b of the manual valve 57 communicated via the oil passage 62f. To the R port 57c of the manual valve 57 through the port 52f and the oil passage 62g. Port 52g, a port 52h communicating with the N port 57a of the manual valve 57 through the oil passage 62h, a pilot port 52i communicating with the oil passage 62i branched from the oil passage 62f, and an oil passage 62j branched from the oil passage 62g. The pilot port 52j and the pilot port 52k communicating with the oil passage 62k branched from the oil passage 62h are provided. The port 52d is connected to the drain oil passage DL via the oil passage 62m branched from the oil passage 62d and the control valve 42Vc, and the port 53e is drained via the oil passage 62n branched from the oil passage 62e and the control valve 42Vd. It is connected to the road DL.

  Further, the second neutral switching valve 52 has a spool valve shaft 52A that is operated by the pilot pressure from the pilot ports 52i, 52j, or 52k and the biasing force of the spring 52s, and the pilot pressure from the pilot ports 52i, 52j, or 52k. In a state in which the supply of oil is stopped, the spool valve shaft 52A is maintained at the steady operation position by the spring 52s, the ports 52a and 52d and 52b and 52e communicate with each other, and the ports 52c, 52f, 52g and 52h are closed. On the other hand, the spool valve shaft 52A is biased to the neutral and limp home position against the spring 52s by the pilot pressure from the pilot ports 52i, 52j, or 52k, and the ports 52a and 52f, 52b and 52g, and 52c and 52h communicate with each other. To do.

  As shown in FIGS. 3 and 8 together with the third shift actuator 43, the third neutral switching valve 53 includes a port 53a communicating with the control pressure supply port 43Ad of the third shift actuator 43 via an oil passage 63a, and a control pressure supply. The port 53B communicates with the port 43Bd via the oil passage 63b, the port 53c communicates with both limp home pressure introduction ports 43Ae and 43Be via the oil passage 63c, and the oil passage 63d with the control valve 43Va through the line. The port 53d connected to the pressure oil passage PL, the port 53e connected to the line pressure oil passage PL via the oil passage 63e through the control valve 43Vb, and the N port 57a of the manual valve 57 communicated via the oil passage 63f. Port 53f and pilot port communicating with oil passage 63g branched from oil passage 63f 3g is provided. The port 53d is connected to the drain oil passage DL via the oil passage 63h branched from the oil passage 63d and the control valve 43Vc, and the port 53e is drained via the oil passage 63i branched from the oil passage 63e and the control valve 43Vd. Connected to the road DL.

  Further, the third neutral switching valve 53 has a spool valve shaft 53A that operates from the pilot port 53g by the pilot pressure and the urging force of the spring 53s. When the supply of the pilot pressure from the pilot port 53g is stopped, the third neutral switching valve 53 is driven by the spring 53s. The spool valve shaft 53A is maintained in the steady operation position, the ports 53a and 53d, 53b and 53e are communicated, and the ports 53c and 53f are closed. On the other hand, supply of the pilot pressure causes the spool valve shaft 53A to be biased to the neutral position against the biasing force of the spring 53s, and the ports 53a, 53d, 53b, 53e are closed to connect the ports 53c and 53f.

  As shown in FIGS. 3 and 9 together with the fourth shift actuator 44, the fourth neutral switching valve 54 includes a port 54a communicating with the control pressure supply port 44Ad of the fourth shift actuator 44 via an oil passage 64a, and a control pressure supply. The port 54B communicates with the port 44Bd via the oil passage 64b, the port 54c communicates with both limp home pressure introduction ports 44Ae and 44Be via the oil passage 64c, and the oil passage 64d with the control valve 44Va. The port 54d connected to the pressure oil passage PL, the port 54e connected to the line pressure oil passage PL via the oil passage 64e via the control valve 44Vb, and the N port 57a of the manual valve 57 communicated via the oil passage 64f. Port 54f and pilot port communicating with oil passage 64g branched from oil passage 64f 4g is provided. The port 54d is connected to the drain oil path DL via the oil path 64h branched from the oil path 64d and the control valve 44Vc, and the port 54e is drained via the oil path 64i branched from the oil path 64e and the control valve 44Vd. It is connected to the road DL.

  Further, the fourth neutral switching valve 54 has a spool valve shaft 54A that is operated by the pilot pressure from the pilot port 54g and the urging force of the spring 54s, and the spring 54s is in a state where the supply of the pilot pressure from the pilot port 54g is stopped. Thus, the spool valve shaft 54A is maintained in the steady operation position, the ports 54a and 54d and the ports 54b and 54e are communicated, and the ports 54c and 54f are closed. On the other hand, the supply of pilot pressure causes the spool valve shaft 54A to be biased to the neutral position against the biasing force of the spring 54s, and the ports 54a, 54d, 54b, 54e are closed, and the ports 54c and 54f communicate.

  The first clutch pressure regulating valve 55 includes a port 55a communicating with a hydraulic chamber (not shown) of the first input clutch 15 via an oil passage 65a, and a control valve 45Va as shown in enlarged views of main parts in FIGS. And a port 55b connected to the line pressure oil passage PL through an oil passage 65b in which the clutch control manual valve 60 is interposed, a port 55c communicating with the D port 57b of the manual valve 57 through the oil passage 65c, and an oil passage 65c. A pilot port 55d that communicates with an oil passage 65d branched from the pipe. The port 55b is connected to the drain oil passage DL via an oil passage 65d branched from the oil passage 65b and a control valve 45Vb.

  Further, the first clutch pressure regulating valve 55 has a spool valve shaft 55A that is operated by the pilot pressure from the pilot port 55d and the urging force of the spring 55s, and in a state where the supply of the pilot pressure from the pilot port 55d is stopped. The spool valve shaft 55A is maintained in the steady operation position by the spring 55s, the ports 55a and 55b communicate with each other, and the port 55c is closed. On the other hand, when the spool valve shaft 55A is urged to the limp home position against the urging force of the spring 55s by supplying pilot pressure from the pilot port 55d, the port 55b is closed and the ports 55a and 55c are communicated with each other and the port 55c. The hydraulic pressure supplied to the 55a side is reduced.

  As shown in FIG. 3 and FIG. 11, the second clutch pressure regulating valve 56 includes a port 56a that communicates with a hydraulic chamber (not shown) of the second clutch 16 via an oil passage 66a, a control valve 46Va, and a clutch. A port 56b connected to the line pressure oil path PL via an oil path 66b in which the control manual valve 60 is interposed, a port 56c communicating with the R port 57c of the manual valve 57 via the oil path 66c, and the oil path 66c It has a pilot port 56d through which the branched oil passage 66d communicates.

  Further, the second clutch pressure regulating valve 56 has a spool valve shaft 56A that is operated by the pilot pressure from the pilot port 56d and the urging force of the spring 56s, and in the state where the supply of the pilot pressure from the pilot port 56d is stopped, The spool valve shaft 56A is maintained at the steady operation position by 56s, the ports 56a and 56b are communicated, and the port 56c is closed. On the other hand, when the spool valve shaft 56A is urged to the limp home position against the urging force of the spring 56s by supplying the pilot pressure, the port 56b is closed and the ports 56a and 56c communicate with each other and are sent from the port 56a to the 56c side. Reduce the hydraulic pressure to be supplied.

  The manual valve 57 includes an N port 57a that communicates with the oil passages 61f, 62h, 63f, and 64f, a D port 57b that communicates with the oil passages 62f and 65c, an oil passage 62g, and an enlarged main portion as shown in FIGS. An R port 57c communicating with 66c, a drain port 57d, a port 57e communicating with an oil passage 67a branched from the line pressure oil passage PL, and a port communicating with a port 58a of a limp home circuit switching valve 58 described later via an oil passage 67b. 57f, a port 57g communicating with the port 58b of the limp home circuit switching valve 58 via the oil passage 66c, and a port 57h communicating with the hydraulic chamber 59C of the limp home circuit switching valve stopper device 59 via the oil passage 67d. Yes.

  Further, the manual valve 57 includes a D position corresponding to the drive range, an N position corresponding to the neutral range, an R position corresponding to the reverse range, and a P position corresponding to the parking range by operating the select lever S by the driver in the passenger compartment. A spool valve shaft 57A is provided.

  When the spool valve shaft 57A is in the D position, that is, the manual valve 57 is in the drive position, the D port 57b and the port 57f, the N port 57a and the R port 57c and the port 57g, the drain port 57d and the port 57h communicate, and the port 57e Closed.

  When the spool valve shaft 57A is in the N position, that is, when the manual valve 57 is in the neutral position, the N port 57a and the port 57e, the D port 57b and the R port 57c and the port 57g, the port 57d and the port 57h communicate, and the port 57e is closed. It is done.

  When the spool valve shaft 57A is in the R position, that is, when the manual valve 57 is in the reverse position, the R port 57c and the port 57e, the N port 57a and the port 57b and the port 57g, the port 57d and the port 57h communicate, and the port 57e is closed. .

  When the spool valve shaft 57A is in the P position, that is, when the manual valve 57 is in the parking position, the N port 57a and the port 57f, the D port 57b and the R port 57c and the port 57g, and the port 57e and the port 57h communicate with each other.

  12 and 13, the limp home circuit switching valve 58 includes a port 58a that communicates with the port 57f of the manual valve 57 via the oil passage 67b, a port 58b that communicates with the port 57g via the oil passage 67c, and a line. An electromagnetic valve having a spool valve shaft 58A that has a line pressure port 58c and a drain port 58d communicating with the pressure oil passage PL and moves to a steady operation position and a limp home position by energization and deenergization from the spring 58s and the ECU 49. It is configured. When power is supplied from the ECU 49, the spool valve shaft 58A is held at the steady operation position against the spring 58s, the port 58a, the port 58b, and the drain port 58d communicate with each other, and the port 58c is closed. On the other hand, when the energization is stopped, the spool valve shaft 58A is moved to the limp home position by the spring 58s, and the port 58a and the port 58c and the port 58b and the port 58d communicate with each other at the limp home position.

  Further, the limp home circuit switching valve 58 is provided with a limp home circuit switching valve stopper device 59. The limp home circuit switching valve stopper device 59 includes a cylinder 59A having a through hole 59Ab, a stopper 59B in which a base 59Ba is slidably fitted into the cylinder 59A and a tip 59Bb projects from the through hole 59Ab, a spring 59s, And a hydraulic chamber 59C formed by the cylinder 59A and the base 59Ba of the stopper 59B. 59Ac is an air vent hole formed in the cylinder 59A in order to ensure the movement of the stopper 59B. At the normal time, the front end 58Bb of the stopper 59B is held at the normal position where it is engaged with the spool valve shaft 58A by the urging force of the spring 59s, while the hydraulic chamber 59C is supplied from the port 57h of the manual valve 57 via the oil passage 67d. The stopper 59B is pushed to the disengaged position against the spring 59s by the hydraulic pressure, and the locking of the spool valve shaft 57A by the tip 58Bb is released.

  Further, the oil passages 65c and 66c are provided with a clutch control manual valve 60 having a spool valve shaft 60A that is operated by operating the shift lever S. The clutch control manual valve 60 is disposed between the line pressure oil path PL and the oil paths 65b and 66b, and the spool valve shaft 60A is line pressure oil at the D position corresponding to the drive range and the R position corresponding to the reverse range. The path PL and the oil paths 65b and 66b are communicated, and the line pressure oil path PL and the oil paths 65b and 66b are closed at the N position corresponding to the neutral range.

  The operating state of each part in the steady running state by the hydraulic control device described above will be described.

  In the steady operation state, the limp home circuit switching valve 58 is energized from the TCU 49 and the spool valve shaft 58A is held at the steady operation position. In this steady operation position, the line pressure introduction port 58c communicating with the line pressure oil path PL is closed, and oil supply from the port 58a of the limp home circuit switching valve 58 to the port 57e of the manual valve 57 via the oil path 67a is performed. The stop state is maintained. Further, the port 57e communicating with the line pressure oil passage PL of the manual valve 57 via the oil passage 67a is shielded, and the hydraulic chamber 59C of the limp home circuit switching valve stopper device 59 is connected to the oil passage 66d and the drain port 57d of the manual valve 57. The stopper 58B is maintained in the engagement position where the spring 58s is engaged with the spool valve shaft 58A by the spring 59s, and the spool valve shaft 58A is reliably held in the steady operation position.

  As a result, the introduction of the link home pressure from the manual valve 57 to the first to fourth neutral switching valves 51 to 54, the first clutch pressure regulating valve 55, and the second clutch pressure regulating valve 56 is stopped, and each of these neutral switching valves. 51 to 54 and the respective spool valve shafts 51A to 56A of the respective clutch pressure regulating valves 55 and 56 are held at the steady operation positions, and the first to fourth shift actuators 41 to 44, the first clutch 15 and the second clutch 16 are Steady operation by operation can be secured.

  That is, the supply of the pilot pressure to the first neutral switching valve 51 is stopped, the spool valve shaft 51A is held at the steady operation position, and the oil passages 61a and 61d and 61b and 61e communicate with each other. Similarly, the supply of the pilot pressure to the second neutral switching valve 52 is stopped, the spool valve shaft 52A is held in the steady operation position, and the oil passages 62a and 62d and 62b and 62e communicate with each other. Similarly, the spool valve shaft 53A of the third neutral switching valve 53 is held in the steady operation position so that the oil passages 63a and 63d and 63b and 63e communicate with each other, and the spool valve shaft 54A of the fourth neutral switching valve 54 is in the steady operation position. So that the oil passages 64a and 64d and 64b and 64e communicate with each other.

  The supply of pilot pressure to the first clutch pressure regulating valve 55 is stopped, the spool valve shaft 55A is held at the steady operation position, and the oil passages 65a and 65d are communicated. Similarly, in the second clutch pressure regulating valve 56, the spool valve shaft 56A is held at the steady operation position, the ports 56a and 56b communicate with each other, and the oil passages 66a and 66d communicate with each other.

  In the steady operation state in which the spool valve shafts 51A to 56A of the first to fourth neutral switching valves 51 to 54 and the first and second clutch pressure regulating valves 55 and 56 are held in the steady operation position, the normally closed type Control valves 41Va to 41Vd, 42Va to 42Vd, 43Va to 43Vd, and 44Va to 44Vd, which are electromagnetic valves, are closed.

  When the first speed is set, the control valve 44Va is opened and the control pressure from the line oil passage PL is introduced into the first transmission hydraulic chamber 44-1 of the fourth shift actuator 44 through the oil passages 64d and 64a. The spool valve shaft 44C moves to the second speed change position by introducing the control pressure into the first speed change hydraulic chamber 44-1. A shift fork 44S interlocked with the movement of the spool valve shaft 44C engages the sync sleeve 34b of the fourth switching mechanism 34 with a spline 21d formed integrally with the driven gear 21b. After that, when the control valve 46Va is opened and the control oil pressure is supplied from the line pressure oil passage PL to the second input clutch 16 through the oil passages 66c and 66a and the second input clutch 16 is engaged, the power from the engine E becomes the second power. The first speed is set by transmitting the input shaft 12.

  When the first speed is set and the control valve 46Va is closed and the control valve 46Vb is opened, the second input clutch 16 is disengaged and the power transmission from the engine E to the second input shaft 12 is stopped. With the second clutch 16 disengaged, the control valve 44Va is closed and the control valve 44Vc is opened to connect the oil passage 64b and the drain oil passage DL. As a result, the pressure in the first shift hydraulic chamber 44-1 is reduced, the spool valve shaft 44A moves from the second shift position to the neutral position, and the synchro sleeve 34b moves to the neutral position by the shift fork 44S to enter the neutral state.

  When setting the second speed, the control valve 42Va is opened and the control pressure from the line oil passage PL is introduced into the second shift hydraulic chamber 42-2 of the second shift actuator 42 through the oil passages 62d and 62a. The spool valve shaft 42C moves to the first shift position by introducing the control pressure into the second shift hydraulic chamber 42-2. The sync sleeve 32b of the second switching mechanism 32 is meshed with a spline 22d formed integrally with the driven gear 22b by the shift fork 42S interlocked with the movement of the spool valve shaft 42C. Thereafter, when the control valve 45Va is opened and the control oil pressure is supplied from the line pressure oil passage PL to the first clutch 15 through the oil passages 65c and 65a and the first input clutch 15 is engaged, the power from the engine E is the first input. The second speed is set by transmitting the shaft 11.

  Further, when the control valve 45Va is closed and the control valve 45Vb is opened with the second speed set, the engagement of the first input clutch 15 is released and the power transmission from the engine E to the first input shaft 11 is stopped. With the first input clutch 15 disengaged, the control valve 42Va is closed and the control valve 42Vc is opened to connect the oil passage 62d and the drain oil passage DL. As a result, the inside of the second shift hydraulic chamber 42-2 is depressurized, the spool valve shaft 42A moves from the first shift position to the neutral position, and the synchro sleeve 32b moves to the neutral position by the shift fork 42S to enter the neutral state.

  Similarly, the third speed is set by the third shift actuator 43 and the second input clutch 16 that are operated by opening / closing the control valves 43Vb, 43Vd and opening / closing the control valves 46Va, 46Vb, or a neutral state is established. Further, the fourth speed is set by the first shift actuator 41 and the first input clutch 15 which are operated by opening / closing the control valves 41Va, 41Vc and opening / closing the control valves 45Va, 45Vb, or the neutral state is set. Further, the fifth speed is set by the third shift actuator 43 and the second input clutch 16 which are operated by opening / closing the control valves 43Vb, 43Vd and opening / closing the control valves 46Va, 46Vb, or a neutral state is established. Sixth speed is set by the first shift actuator 41 and the first input clutch 15 which are operated by opening / closing the control valves 41Va, 41Vc and opening / closing the control valves 45Va, 45Vb, or a neutral state is established. As a result, a forward speed of 1st to 6th speed is obtained.

  When the reverse speed is set, the control valve 42Vb is opened and the control pressure from the line oil passage PL is introduced into the first transmission hydraulic chamber 42-1 of the second shift actuator 42 through the oil passages 62e and 62b. The spool valve shaft 42C moves to the second shift position by introducing the control pressure into the first shift hydraulic chamber 42-1. The sync sleeve 32b of the second switching mechanism 32 meshes with a spline 27d formed integrally with the driven gear 27b by the shift fork 42S interlocking with the movement of the spool valve shaft 42C. Thereafter, when the control valve 46Va is opened and the control oil pressure is supplied from the line pressure oil passage PL to the second input clutch 16 through the oil passages 66c and 66a and the second input clutch 16 is engaged, the power from the engine E is second. The reverse gear is set by being transmitted to the input shaft 12.

  If the control valve 46Va is closed and the control valve 46Vb is opened with the reverse gear set, the engagement of the second clutch 16 is released and the power transmission from the engine E to the second input shaft 12 is stopped. With the second input clutch 16 disengaged, the control valve 42Vb is closed, the control valve 42Vd is opened, and the oil passage 62e and the drain oil passage DL are communicated. As a result, the pressure in the first shift hydraulic chamber 42-1 is reduced, the spool valve shaft 42A moves from the second shift position to the neutral position, and the synchro sleeve 32b moves to the neutral position by the shift fork 42S to enter the neutral state.

  When the transmission gear train is set to any one of the first to sixth gears or the reverse gear, and a failure occurs in the electric system, the control valves 41Va, 41Vc, 42Va, 42Vc including normally closed electromagnetic valves are used. 43Va, 43Vc, 44Va, and 44Vc are closed, but the transmission gear train is maintained by the meshing resistance of the meshed sleeve and the spline and the detent mechanism, so that the vehicle can travel. If the select lever S is selected to the neutral range while this transmission gear train is maintained, the clutch control manual valve 60 closes the line pressure oil path PL and the oil paths 65b and 66b, and the first input clutch 15 The hydraulic pressure supply to the second input clutch 16 is stopped, the power transmission from the engine E to the first input shaft 11 or the second input shaft 12 is cut off, and the vehicle stops.

  Further, energization from the ECU 49 to the limp home circuit switching valve 58 is stopped due to the failure of the electric system, but the spool valve shaft 58A is locked to the stopper 59B of the limp circuit switching valve stopper device 59 to the normal operation position. Maintained.

  Here, when the parking range is selected by operating the select lever S, it switches to the limp home circuit, and when the drive range is selected again, the limp home control is performed and the second speed is controlled regardless of the state of the transmission gear train before the energization is stopped. It is possible to travel forward with this transmission gear train. If the reverse range is selected after the parking range is selected by the select lever S, the vehicle can travel backward. This will be specifically described.

  For example, when the transmission gear train is 6th speed, a failure occurs in the electric system, and the 6th speed transmission gear train in which the spline 26d provided integrally with the driven gear 26b and the sync sleeve 34b of the first switching mechanism 34 mesh with each other is maintained. In this state, the first shift actuator 41 is in a state in which the spool valve shaft 41 is stopped at the first shift position as indicated by a one-dot chain line in FIG. The first drain hole 41Ag is closed by the diameter portion 41Db, and the first limp home pressure introduction port 41Ae and the first communication port 41Af are opened by the groove 41Dd, while the large diameter portion 41Eb of the second spool portion 41E is the second limp home pressure. The introduction port 41Be is closed, and the second communication port 41Bf and the second drain port 41Bg are opened by the groove 41Ed. Further, the spool valves 42A, 43A, 44A of the second shift actuator 42, the third actuator 43, and the fourth actuator 44 are maintained at neutral positions indicated by solid lines in FIGS. 7, 8, and 9, respectively.

  When the shift lever S is selected from the neutral range to the parking range in this state, the spool valve shaft 57A of the manual valve 57 moves to the P position, and is connected to the line pressure oil path PL via the oil path 67a in this P position state. The port 57e connected to the hydraulic chamber 59C of the limp home circuit switching valve stopper device 59 communicates with the port 57e through the oil passage 67d. As a result, the line pressure is supplied to the hydraulic chamber 59C of the limp home circuit switching valve stopper device 59 via the oil passage 67a, the manual valve 57 and the oil passage 67d, and the stopper 59B is pushed to the disengaged position against the spring 59s. Thus, the locking of the spool valve shaft 58A by the tip portion 59Bb is released. Further, the port 57f and the N port 57a communicate with each other, and the D port 57b and the N port 57c are drained through the port 57g.

  The spool valve shaft 58A of the limp home circuit switching valve 58 released from the locking by the stopper 59B is moved from the steady operation position to the limp home position by the urging force of the spring 58s. When the spool valve shaft 58A is in the limp home position, the ports 58a and 58c and the ports 58b and 58d of the limp home circuit switching valve 58 communicate with each other.

  The line pressure introduced into the port 58c of the limp home circuit switching valve 58 by the communication between the port 57f of the manual valve 57 and the N port 57a is introduced from the port 58a to the port 57f of the manual valve 57 through the oil passage 67b. The oil passage 61f and the oil passage 61g branched from the oil passage 61f are introduced as a limp home pressure to the port 51f of the first neutral switching valve 51 and introduced into the pilot port 51g as a pilot pressure.

  As the pilot pressure is introduced, the first neutral switching valve 51 moves the spool valve shaft 51A from the steady operation position to the neutral position against the spring 51s, and the port 51f and the oil path 61c connected to the oil path 61f. Is connected to the port 52c to which is connected. Thereby, the limp home pressure introduced into the port 51f of the first neutral switching valve 51 is introduced into the first limp home pressure introduction port 41Ae and the second limp home pressure introduction port 41Be of the first shift actuator 41 via the oil passage 61c. Is done.

  Here, the second limp home pressure introduction port 41Be of the first shift actuator 41 is closed by the second spool portion 41E of the spool shaft valve 41C, but the limp home pressure is introduced from the opened first limp home pressure introduction 41Ae. The introduced limp home pressure is introduced into the first neutral hydraulic chamber 41Dn through the groove 41Dd and the oil passage 41Ai of the first spool portion 41D. The spool valve shaft 43C is moved from the first shift position indicated by the alternate long and short dash line to the neutral position indicated by the solid line by the limp home pressure introduced into the first neutral hydraulic chamber 41Dn, and the first limp home pressure introduction port 41Ae is moved to the first position at the neutral position. The spool valve shaft 41C is closed at its neutral position by being closed by the one spool portion 41D. In synchronization with the movement of the spool valve shaft 41C from the first shift position to the neutral position, the sync fork 41S is engaged with the spline 26d formed integrally with the driven gear 26b by the shift fork 41S. To the neutral position meshed only with the synchro hub 31a, stopped at the neutral position, and maintained at this position.

  Similarly, the limp home pressure is introduced from the N port 57a of the manual valve 57 to the port 52h of the second neutral switching valve 52 via the oil passage 62h, and then to the pilot port 51i via the oil passage 62k branched from the oil passage 62h. Pilot pressure is introduced. With the introduction of the pilot pressure, the spool valve shaft 52A of the second neutral switching valve 52 moves from the steady operation position to the neutral and limp home position, and the first limp home pressure introduction port 42Ae and the second limp of the second shift actuator 42 are obtained. The limp home pressure is introduced into the home pressure introduction port 42Be.

  Further, limp home pressure is introduced from the N port 57a of the manual valve 57 to the port 53f of the third neutral switching valve 53 through the oil passage 63f, and the pilot pressure is applied from the oil passage 63g branched from the oil passage 63f to the pilot port 53g. be introduced. With the introduction of the pilot pressure, the spool valve shaft 53A moves from the steady operation position to the neutral position, and is introduced into the limp home pressure introduction ports 43Ae and 43Be of the third seat actuator 43. Further, limp home pressure is introduced from the N port 57a of the manual valve 57 to the port 54f of the fourth neutral switching valve 54 through the oil passage 64f, and the pilot port 54g is piloted to the pilot port 54g through the oil passage 64g branched from the oil passage 64f. Pressure is introduced. By introducing the pilot pressure, the spool valve shaft 54A moves from the steady operation position to the neutral position, and the limp home pressure is introduced into the first limp home pressure introduction port 44Ae and the second limp home pressure introduction port 44Be of the fourth seat actuator 44. Is done.

  In this way, the shift lever S is selectively operated from the parking range to the neutral range, and the spool valve shaft 57A of the manual valve 57 is switched from the P position to the N position, whereby the first limp home pressure introduction port 41Ae of the first shift actuator 41 is obtained. The second limp home pressure introduction port 41Be, the first limp home pressure introduction port 42Ae and the second limp home pressure introduction port 42Be of the second shift actuator 42, the first limp home pressure introduction port 43Ae of the third shift actuator 43 and the second limp home pressure introduction port 42Ae. By introducing the limp home pressure into the 2 limp home pressure introduction port 43Be and the second limp home pressure introduction port 44Be of the fourth shift actuator 44, for example, the spline of the first shift actuator 41 located at the second shift position is obtained. Valve shaft 41C, spool valve shaft 42C of second shift actuator 42 located at the first shift position or second shift position, and third shift actuator 43 located at the first shift position or second shift position. Similarly, the spool valve shaft 43C and the spool valve shaft 44C of the fourth shift actuator 44 located at the second shift position are respectively moved to the neutral position, and the respective sync sleeves of the first to fourth switching mechanisms 31 to 34 are moved. 31b, 32b, 33b and 34b are all held in the neutral position.

  After that, when the drive range is selected by operating the shift lever S, the spool valve shaft 57A of the manual valve 57 moves to the D position in conjunction therewith. When the spool valve shaft 57A is in the D position, the D port 57b and the port 57f of the manual valve 57, the N port 57a and the R port 57c and the port 57g, the drain port 57d and the port 57h communicate, and the port 57e is closed.

  As a result, the oil passages 61f, 62h, 63f, and 64f connected to the N port 57a are drained through the manual valve 57 and the limp home circuit switching valve 58, and the first neutral switching valve 51, the third neutral switching valve 53, and the first The pilot pressure to the 4-neutral switching valve 54 decreases, and the spool valve shafts 51A, 53A, 54A are moved to the steady operation positions by the springs 51s, 53s, 54s, respectively.

  On the other hand, line pressure is introduced into the oil passage 62f and the oil passage 65c connected to the D port 57b of the manual valve 57. It is introduced as a control pressure from the oil passage 62f to the port 52f of the second neutral switching valve 52, and is introduced as a pilot pressure to the pilot port 52i through the oil passage 62i branched from the oil passage 62f.

  In the second neutral switching valve 52, the spool valve shaft 52A is moved to the neutral and limp home position against the spring 52s by the pilot pressure introduced from the pilot port 52i and is held, and the port 52f connected to the oil passage 62f. And the port 52a to which the oil passage 62b is connected. As a result, the control pressure introduced from the oil passage 62f to the port 52f of the second neutral switching valve 52 is introduced from the port 52a to the second speed change hydraulic chamber 42-2 of the second shift actuator 42 via the oil passage 62a. By introducing the control pressure into the second speed change hydraulic chamber 42-2, the control pressure acts on the end face 42Es of the second spool portion 42E, and the spool valve shaft 42C moves to the first speed change position. In synchronization with the movement of the spool valve shaft 42C, the sync fork 32S of the second switching mechanism 32 is engaged with the spline 22d formed integrally with the driven gear 22b by the shift fork 42S.

  On the other hand, the first clutch pressure regulating valve 55 is introduced as control pressure from the oil passage 65c to the port 55c, and pilot pressure is introduced from the oil passage 65d branched from the oil passage 65c to the pilot port 55d. The first clutch pressure regulating valve 55 is configured such that the spool valve shaft 55A is moved to the limp home position against the spring 55s by the pilot pressure introduced from the pilot port 55d and held, and the port 55c connected to the oil passage 65c and the oil The port 52a to which the path 65a is connected communicates. As a result, the control pressure from the oil passage 65a is reduced and the control pressure is introduced to the first clutch 15 via the oil passage 65a, and the first clutch 15 is engaged in the half-clutch state, whereby the transmission gear train is in the second speed. It is set to be able to travel forward.

  If the neutral range is selected from the drive range of the shift lever S in this forward traveling state, the spool valve shaft 57A moves from the D position to the N position in conjunction with the operation of the shift lever S, and the D port 57b of the manual valve 57 is moved. Let it drain. As a result, the introduction of the control pressure from the oil passage 65c to the first clutch 15 is stopped and the engagement of the first clutch 15 is released, and the introduction of the pilot pressure to the pilot port 55d is stopped and the spool valve shaft 55A is stopped by the spring 55s. Moves to the steady operation position. The limp home pressure is introduced from the N port 57a of the manual valve 57 to the port 52h of the second neutral switching valve 52 through the oil passage 62h, the pilot pressure is introduced from the oil passage 62h, and the second neutral switching valve 52 The spool valve shaft 52A is moved from the steady operation position to the neutral and limp home position, and the sync fork 42S is synchronized with the spline 22d formed integrally with the driven gear 22b. The vehicle moves to a neutral position that meshes only with the hub 32a, becomes a neutral state, and stops traveling forward.

  On the other hand, when the shift lever S is selected from the neutral range to the reverse range, the spool valve shaft 57A of the manual valve 57 moves from the N position to the R position in conjunction with the operation of the shift lever S. When the spool valve shaft 57A is in the R position, the R port 57c and the port 57f of the manual valve 57 communicate with the N port 57a and the D port 57b and the port 57g, and the port 57d is closed. As a result, the line pressure is introduced into the oil passage 62g and the oil passage 66b connected to the R port 57c of the manual valve 57. The oil passage 62g and the oil passage 62j branched from the oil passage 62g are introduced as a control pressure into the port 52g of the second neutral switching valve 52, and introduced into the pilot port 52j as a pilot pressure.

  In connection with the introduction of the pilot pressure from the pilot port 52j, the second neutral switching valve 52 is held by moving the spool valve shaft 51A to the neutral and limp home position against the spring 52s and connected to the oil passage 62g. The port 52g communicates with the port 52b to which the oil passage 62a is connected. As a result, the control pressure introduced from the oil passage 62g to the port 52g of the second neutral switching valve 52 is introduced from the port 52b to the first shift hydraulic chamber 42-1 of the second shift actuator 42 via the oil passage 62a. By introducing the control pressure into the first speed change hydraulic chamber 42-1, the control pressure acts on the end face 42Ds of the first spool portion 42D, the spool valve shaft 42C moves to the second speed change position, and the shift fork 42S performs the second switching. The synchro sleeve 32b of the mechanism 32 is engaged with a spline 27d formed integrally with the driven gear 27b.

  On the other hand, the second clutch pressure adjusting valve 56 is introduced as control pressure from the oil passage 66c to the port 56c, and pilot pressure is introduced from the oil passage 66d branched from the oil passage 66c to the pilot port 56d. The second clutch pressure regulating valve 56 is configured such that the spool valve shaft 56A moves to the limp home position against the spring 56s by the pilot pressure introduced from the pilot port 56d and is held, and the port 56c connected to the oil passage 66c and the oil The port 56a to which the path 66a is connected communicates. As a result, the control pressure from the oil passage 66c is reduced and the control pressure is introduced into the second clutch 16 through the oil passage 66a, and the second clutch 16 is engaged in the half-clutch state, whereby the transmission gear train is moved to the reverse gear. When set to, reverse travel is possible.

  In this reverse travel state, when the shift lever S is selected from the reverse position to the neutral position, the spool valve shaft 57A moves from the R position to the N position in conjunction with the operation of the shift lever S, and the R port 57c of the manual valve 57 is moved. Let it drain. As a result, the introduction of the control pressure from the oil passage 66c to the second clutch 16 is stopped and the engagement of the second clutch 16 is released, and the introduction of the pilot pressure to the pilot port 56d is stopped, and the spool valve shaft 56A is stopped by the spring 56s. Moves to the steady operation position.

  Further, the limp home pressure is introduced from the N port 57a of the manual valve 57 to the oil passage 62h and the oil passage 62k to the port 52h of the second neutral switching valve 52, the pilot pressure is introduced to the pilot port 51k, and the second neutral switching valve 52. The spool valve shaft 52A moves from the steady operation position to the neutral position. As a result, the limp pressure is introduced from the oil passage 62c to the first limp home pressure introduction port 42Ae and the second limp home pressure introduction port 42Be, and the spool valve shaft 42C moves from the second shift position to the neutral position. A neutral position in which the synchro sleeve 32b of the second switching mechanism 32 is engaged with the spline 27d formed integrally with the driven gear 27b by the shift fork 42S in conjunction with the movement of the spool valve shaft 42, and is engaged only with the synchro hub 32a. To move to the neutral state and reverse travel stops.

  Therefore, according to the present embodiment configured as described above, when an electric system failure occurs in the electric system, the limp home circuit switching valve 58 is constantly operated by operating the select lever S to select the parking range. The operating state is switched to the limp home state, and the limp home pressure is introduced from the neutral switching valves 51 to 54 to the first to fourth shift actuators 41 to 44, so that the spool valve shaft 41A of each shift actuator 41 to 44 is obtained. -44A is held in the neutral position or moved to the neutral position. After that, by operating the shift lever S to select the drive range, the control pressure is introduced to the second shift actuator 42 to select the second speed, and the first input clutch 15 is engaged and the second speed gear stage is selected. Is established and forward travel becomes possible. When the neutral range is selected by operating the shift lever S from this forward traveling state, the engagement of the first input clutch 15 is released, and the second shift actuator 42 moves to the neutral position and stops traveling. Similarly, by selecting the reverse range from the parking range or the neutral range, the control pressure is introduced to the second shift actuator 42 to select the reverse gear, and the second input clutch 16 is engaged to establish the reverse gear. When reverse travel is enabled, when the neutral range is selected by operating the shift lever S from this reverse travel state, the engagement of the second input clutch 16 is released, and the second shift actuator 42 moves to the neutral position and stops traveling. To do.

  As a result, even when an electrical failure occurs, the shift actuators 41 to 44 are switched or held in the neutral position in accordance with the operation of the select lever S to the parking range, and then the select rubber S is moved to the drive range or reverse range. Can be stably moved forward or backward, and can be stopped by operating the shift lever S and selecting the neutral range in the forward or backward travel.

  Moreover, the actuators 41 to 44 can be appropriately operated by a simple configuration and hydraulic control by the limp home circuit switching valve 58, the manual valve 57, the neutral switching valves 51 to 54, and the clutch pressure regulating valves 55 and 56. In addition, even when an electric system failure occurs without complicating the hydraulic control, forward traveling and backward traveling can be performed only by operating the select lever S, and the safety of the vehicle can be ensured.

(Second Embodiment)
A second embodiment of the present invention will be described with reference to FIG. This embodiment is different from the first embodiment only in the second neutral switching valve, and the other configuration is the same, and the second neutral switching valve will be mainly described.

  FIG. 14 is an explanatory diagram of a limp home circuit corresponding to FIG. 12 showing the main part of the second embodiment, in which a second neutral switching valve 72 is arranged in place of the second neutral switching valve 52 in FIG. The configuration is the same as that of the first embodiment, and a detailed description of the portion is omitted by attaching the reference numerals corresponding to those in FIG.

  The second neutral switching valve 72 includes a port 72a that communicates with the control pressure supply port 42Bd of the second shift actuator 42 via the oil passage 62a, a port 72b that communicates with the control pressure supply port 42Ad via the oil passage 62b, both limp A port 72c communicating with the home pressure introducing ports 42Ae and 42Be via an oil passage 62c, a port 72d connected to the oil passage 62d with the control valve 42Va, and a port 72e connected to the oil passage 62e with the control valve 42Vb. , A port 72f communicating with the D port 57b of the manual valve 57 via the oil passage 62f, a port 72g communicating with the R port 57c of the manual valve 57 via the oil passage 62g, and the N of the manual valve 57 via the oil passage 62h. From port 72h communicating with port 57a, from oil passage 62f Pilot port 72i communicating with the oil passage 62i, pilot port 72j which communicates with the oil passage 62j branched from the oil passage 62 g, and a pilot port 72k communicating with the oil passage 62k branched from the oil passage 62h.

  Further, the second neutral switching valve 72 has a spool valve shaft 72A that is operated by the pilot pressure from the pilot ports 72i, 72j, 72k and the biasing force of the pair of springs 72s, 72s. The spool valve shaft 72A is urged to the first limp home position by the pilot pressure from the pilot ports 72i and 72k, and the ports 72a and 72f and the ports 72c and 72h communicate with each other. On the other hand, the spool valve shaft 72A is biased to the second limp home position by the pilot pressure from the pilot port 72j, and the ports 72b and 72g communicate with each other. Further, when the supply of pilot pressure from the pilot ports 72i and 72k is stopped, the spool valve shaft 72A is maintained at the steady operation position by the springs 72s and 72s, and the ports 72a and 72d and the ports 72b and 72e communicate with each other.

  In the steady running state by the hydraulic control apparatus configured as described above, the limp home circuit switching valve 58 is energized from the ECU 49 and the spool valve shaft 58A is held at the steady operation position as in the first embodiment. .

  As a result, the introduction of limp home pressure from the manual valve 57 to the neutral switching valves 51, 53, 54, 72, the first clutch pressure regulating valve 55, and the second clutch pressure regulating valve 56 is stopped, and the first to fourth shifts are performed. Steady operation can be ensured by the operation of the actuators 41 to 44 and the first clutch 15 and the second clutch 16.

  When the transmission gear train is in any of the first to sixth gears or the reverse gear, if a failure occurs in the electric system, control valves 41Va, 41Vc, 42Va, 42Vc, 43Va, which are normally closed electromagnetic valves, 43Vc, 44Va, and 44Vc are closed, but the transmission gear train is maintained by the meshing resistance between the meshed sleeve and the spline and the detent mechanism. When the select lever S is selected to the neutral range under these transmission gear trains, the hydraulic pressure supply to the first input clutch 15 and the second input clutch 16 is stopped by the clutch control manual valve 60, so The power transmission to the first input shaft 11 and the second input shaft 12 is interrupted, and the vehicle can be stopped.

  When the parking lever is selected from the neutral range in this state, the line pressure is supplied to the hydraulic chamber 59C of the limp home circuit switching valve stopper device 59, and the stopper 59B is pushed, as in the first embodiment. Thus, the lock of the spool valve shaft 58A of the limp home circuit switching valve 58 is released.

  The spool valve shaft 58A released from the locking by the stopper 59B is moved from the steady operation position to the limp home position by the urging force of the spring 58s. At this limp home position, the ports 58a, 58c and 58c of the limp home circuit switching valve 58 are moved. 58b and port 58d communicate.

  Due to the communication between the port 57f of the manual valve 57 and the N port 57a, the limp home pressure is introduced from the N port 57a of the manual valve 57 to the oil passage 61f and from the oil passage 61f to the port 51f of the first neutral switching valve 51 to the pilot port 51g. Pilot pressure is introduced. As a result, the spool valve shaft 51A moves from the steady operation position to the neutral position, and the limp home pressure is supplied from the port 51f through the oil passage 61c to the first limp home pressure introduction port 41Ae and the second limp home pressure. It is introduced into the introduction port 41Be.

  Similarly, the limp home pressure is introduced into the port 72h of the second neutral switching valve 72 through the oil passage 62h from the N port 57a of the manual valve 57 and the oil passage 62i separated from the oil passage 62h, and the pilot pressure is applied to the pilot port 72i. be introduced. By introducing the pilot pressure, the spool valve shaft 72A moves to the first limp home position, the ports 72h and 72c communicate with each other, and the limp home pressure is supplied from the port 72c through the oil passage 62c to the first limp of the second shift actuator 42. The pressure is introduced into the home pressure introduction port 42Ae and the first limp home pressure introduction port 42Be.

  Similarly, limp home pressure is introduced from the N port 57a of the manual valve 57 to the oil passages 63f and 64f to the ports 53f and 54f of the third and fourth neutral switching valves 53 and 54, and the pilot pressure is applied to the pilot ports 53g and 54g. Is introduced. As a result, the spool valve shafts 53A and 54A move from the steady operation position to the neutral position, and the limp home pressure is supplied from the ports 53f and 54f to the limp home pressure introduction ports 43Ae of the third shift actuator 43 via the oil passages 63c and 64c. 43Be and limp home pressure introduction ports 44Ae, 44Be of the fourth shift actuator 44. Accordingly, the spool shaft valves 41A to 44A of the first to fourth shift actuators 41 to 44 are moved to the neutral position or maintained at the neutral position, so that the sync hubs of the first to fourth switching mechanisms 31 to 34 are operated. 31b to 34b are maintained in the neutral position.

  Further, when the drive range is selected by operating the shift lever S, the spool valve shaft 57A of the manual valve 57 moves to the D position in conjunction with the operation of the shift lever S, and the D port 57b and the port 57f of the manual valve 57 are moved. The N port 57a and the R port 57c communicate with the port 57g, the port 57d communicates with the port 57h, and the port 57d is closed.

  As a result, the oil passages 61f, 62h, 63f and 64f connected to the N port 57a are drained through the manual valve 57 and the limp home circuit switching valve 58, and the first neutral switching valve 51, the third neutral switching valve 53 and the first The pilot pressure to the 4-neutral switching valve 54 decreases, and the spool valve shafts 551A, 53A, 54A are moved to the steady operation positions by the springs 51s, 53s, 54s, respectively.

  On the other hand, line pressure is introduced into the oil passage 62f and the oil passage 65c connected to the D port 57a of the manual valve 57. The control pressure is introduced from the oil passage 62f and the oil passage 62i branched from the oil passage 62f to the port 72f of the second neutral switching valve 72, and the pilot pressure is introduced to the pilot port 72i.

  In connection with the introduction of the pilot pressure from the pilot port 72i, the second neutral switching valve 72 is connected to the oil passage 62f by moving the spool valve shaft 72A to the first limp home position against the springs 72s, 72s. The port 72a connected to the port 72f and the oil passage 62a communicates. As a result, the control pressure introduced from the oil passage 62f to the port 72f of the second neutral switching valve 72 is introduced from the port 72a to the second shift hydraulic chamber 42-2 of the second shift actuator 42 via the oil passage 62b. The spool valve shaft 42C is moved to the first shift position by introducing the control pressure into the second shift hydraulic chamber 42-2, and the sync sleeve 32b of the second switching mechanism 32 is formed integrally with the driven gear 22b by the shift fork 42S. Mesh with the spline 22d.

  On the other hand, in the first clutch pressure regulating valve 55, control pressure is introduced from the oil passage 65c to the port 55c, and pilot pressure is introduced to the pilot port 55d via the oil passage 65d branched from the oil passage 65c. In the first clutch pressure regulating valve 55, the spool valve shaft 55A moves to the limp home position against the spring 55s by the introduced pilot pressure and is held, and the port 55c connected to the oil passage 65c is connected to the oil passage 65a. The connected port 52a communicates. As a result, the control pressure from the oil passage 65c is reduced and introduced into the first clutch 15 via the oil passage 65a, and the first clutch 15 is engaged in a half-clutch state. As a result, the transmission gear train is set to the second speed, and forward traveling is enabled.

  When the shift lever S is selected to the neutral range in this forward traveling state, the spool valve shaft 57A moves from the D position to the N position in conjunction with the operation of the shift lever S, and the D port 57b of the manual valve 57 is drained. Thereby, the introduction of the control pressure from the oil passage 65c to the first clutch 15 is stopped, the engagement of the first clutch 15 is released, and the forward traveling is stopped.

  On the other hand, when the reverse position of the shift lever S is selected from the neutral range or the drive range, the spool valve shaft 57A of the manual valve 57 moves to the R position in conjunction with the operation of the shift lever S. When the spool valve shaft 57A is in the R position, the R port 57c and the port 57f of the manual valve 57 communicate with the N port 57a and the D port 57b and the port 57g, and the port 57d is closed.

  As a result, the line pressure is introduced into the oil passage 62g and the oil passage 66c connected to the R port 57c of the manual valve 57. The oil passage 62g and the oil passage 62j branched from the oil passage 62g are introduced as a control pressure into the port 52g of the second neutral switching valve 72 and introduced into the pilot port 72j as a pilot pressure.

  With the introduction of the pilot pressure from the pilot port 52j, the second neutral switching valve 72 is held by moving the spool valve shaft 72A to the second limp home position against the spring 52s and connected to the oil passage 62g. The port 72g communicates with the port 72b to which the oil passage 62a is connected. As a result, the control pressure introduced from the oil passage 62g to the port 72g of the second neutral switching valve 72 is introduced from the port 72b to the first transmission hydraulic chamber 42-1 of the second shift actuator 42 via the oil passage 62a. The spool valve shaft 42C moves to the second shift position by introducing the control pressure into the first shift hydraulic chamber 42-1, and the synchro sleeve 32b of the second switching mechanism 32 is formed integrally with the driven gear 27b by the shift fork 42S. Mesh with the spline 27d.

  On the other hand, the second clutch pressure adjusting valve 56 is introduced as control pressure from the oil passage 66c to the port 56c, and pilot pressure is introduced from the oil passage 66d branched from the oil passage 66c to the pilot port 56d. The second clutch pressure regulating valve 56 is configured such that the spool valve shaft 56A is moved to the neutral position against the spring 56s by the pilot pressure introduced from the pilot port 56d and held, and the port 56c connected to the oil path 66b and the oil path The port 56a to which 66a is connected communicates. As a result, the control pressure from the oil passage 66c is reduced, the control pressure is introduced from the oil passage 66a to the second clutch 16, and the second clutch 16 is engaged in the half-clutch state, whereby the transmission gear train is set to the reverse gear. This makes it possible to travel backwards.

  In this reverse travel state, when the shift lever S is selected from the reverse range to the neutral range, the spool valve shaft 57A moves from the R position to the N position in conjunction with the operation of the shift lever S, and the R port 57c of the manual valve 57 is moved. Let it drain. Thereby, the introduction of the control pressure from the oil passage 66c to the second clutch 16 is stopped, the engagement of the second clutch 16 is released, and the reverse travel is stopped.

  Therefore, according to the present embodiment configured as described above, when an electric system failure occurs, the limp home circuit switching valve 58 is moved from the steady operation position by operating the select lever S to select the parking range. The spool valve shafts of the first to fourth shift actuators 41 to 44 are switched to the limp home positions and the limp home pressure is introduced from the neutral switching valves 41 to 44 to the first to fourth shift actuators 41. 41A to 44A are held in the neutral position or moved to the neutral position. After that, by operating the shift lever S to select the drive range, the control pressure is introduced to the second shift actuator 42 to select the second speed, and the first input clutch 15 is engaged and the second speed gear stage is selected. Is established and forward travel becomes possible. When the neutral position is selected by operating the shift lever S from this forward traveling state, the engagement of the first input clutch 15 is released and the traveling is stopped. Similarly, by selecting the reverse range from the parking range, neutral range position or drive range, the control pressure is introduced to the second shift actuator 42 and the reverse gear is selected, and the second input clutch 16 is engaged and the reverse gear is selected. Is established and reverse travel becomes possible, and when the neutral range is selected by operating the shift lever S from this reverse travel state, the engagement of the second input clutch 16 is released and the reverse travel is stopped.

  Therefore, according to the present embodiment, in addition to the first embodiment, even if a failure occurs in the electric system when the transmission gear train is in the first to sixth gears or the reverse gear, the shift lever After selecting S as the parking range and switching to the limp home circuit, the vehicle can move forward or reverse by directly selecting the reverse range from the drive range or the drive range from the reverse range without going through the neutral range.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the invention.

  For example, in each of the above-described embodiments, the description has been given of an example of an automatic transmission having a forward 6-speed shift and a reverse 1-speed shift. However, the present invention can also be applied to an automatic transmission having other shift stages such as other forward 5 speeds. In addition, although it is configured to be able to travel in the second speed and the reverse speed at the limp home, it is not limited to the second speed but can be set to another forward speed.

1 is a skeleton diagram showing an automatic transmission having a hydraulic control apparatus according to a first embodiment of the present invention. It is control system explanatory drawing of an automatic transmission. It is a hydraulic circuit diagram which shows the hydraulic control apparatus of an automatic transmission. It is a hydraulic circuit diagram which shows the hydraulic control apparatus of an automatic transmission. It is explanatory drawing of a 1st shift actuator and a 1st neutral switching valve. It is explanatory drawing of a 1st shift actuator. It is limp home circuit explanatory drawing containing a 2nd shift actuator, a 2nd neutral switching valve, a manual valve, a limp home circuit switching valve, a limp home circuit switching valve stopper device, etc. It is explanatory drawing of a 3rd shift actuator and a 3rd neutral switching valve. It is explanatory drawing of a 3rd shift actuator and a 3rd neutral switching valve. It is explanatory drawing of a 1st clutch pressure regulation valve. It is explanatory drawing of a 2nd clutch pressure regulation valve. It is explanatory drawing of a manual valve and a limp home circuit switching valve. It is explanatory drawing of a manual valve and a limp home circuit switching valve. It is explanatory drawing of the hydraulic control apparatus which is 2nd Embodiment of this invention.

Explanation of symbols

11 1st input shaft 12 2nd input shaft 13 Output shaft 15 1st input clutch 16 2nd input clutch 21a-27a Drive gear 21b-27b Drive gear 31-34 1st-4th switching mechanism 41-44 1st-1st 4 shift actuators 41A to 44A First cylinder part 41B to 44B Second cylinder part 41Dn to 44Dn First neutral hydraulic chamber 41En to 44En Second neutral hydraulic chamber 41Ae to 44Ae First communication port 41Be to 44Be Second communication port 41Af to 44Af 1st limp home pressure introduction port 41Bf-44Bf 1st limp home pressure introduction port 51-54 1st-4th neutral switching valve 57 Manual valve 58 Limp home switching valve

Claims (3)

An input shaft for selectively transmitting power from the engine by engaging and releasing the input clutch, an output shaft for transmitting power to the wheels, a plurality of drive gears provided on the input shaft, and the output shaft In a hydraulic control device for an automatic transmission comprising a plurality of transmission gear trains formed by a driven gear meshing with a drive gear,
A plurality of shift actuators for selectively setting a transmission gear train for transmitting power from the input shaft to the output shaft from the plurality of transmission gear trains;
A neutral switching valve arranged corresponding to each of the shift actuators;
A manual valve that can be switched to the P position, N position, D position, and R position according to the selection of the parking range, neutral range, drive range, and reverse range of the shift lever in the event of an electrical failure;
When the manual valve is in the N position or P position, each neutral switching valve is switched from the steady operation state to the neutral state, and hydraulic pressure is supplied to each shift actuator so that each shift actuator is in the neutral position, and the manual valve is in the D position. Alternatively, in the R position state, hydraulic pressure is supplied to the shift actuator such that a specific neutral switching valve among the plurality of neutral switching valves is switched to the limp home state and a transmission gear train for transmitting power by the shift actuator is set. A hydraulic control device for an automatic transmission. An input shaft for selectively transmitting power from the engine by engaging and releasing the input clutch, an output shaft for transmitting power to the wheels, a plurality of drive gears provided on the input shaft, and the output shaft In a hydraulic control device for an automatic transmission comprising a plurality of transmission gear trains formed by a driven gear meshing with a drive gear,
A specific shift actuator that sets a transmission gear train for transmitting power from the input shaft to the output shaft among the plurality of transmission gear trains as a specific forward transmission gear train or a reverse transmission gear train, and a transmission gear that transmits the power A general shift actuator that sets the train to another transmission gear train;
A specific neutral switching valve and a general neutral switching valve arranged corresponding to the specific shift actuator and the general shift actuator,
A manual valve that can be switched to a P position, an N position, a D position, and an R position state according to the selection of the parking range, neutral range, drive range, and reverse range of the shift lever in the event of an electrical failure;
A limp home switching valve for switching the hydraulic circuit from the steady operation circuit to the limp home circuit in the P-position state of the shift lever;
When the electric system fails, the hydraulic circuit is switched from the steady operation circuit to the limp home circuit by the limp home switching valve in the P position state of the shift lever.
When the manual valve is in the N-position or P-position, the specific neutral switching valve supplies a specific shift actuator hydraulic pressure so that the specific shift actuator is in a neutral position. Supply hydraulic pressure to the actuator so that the general shift actuator is in the neutral position,
When the manual valve is in the D position or R position, the specific neutral switching valve switches the transmission gear train to which the specific shift actuator transmits power to the specific forward transmission gear train or the reverse transmission gear train. Hydraulic control device for automatic transmission. Each of the above shift actuators
A first cylinder part and a second cylinder part arranged opposite to each other on the same axis;
The first cylinder is slidably mounted in the first cylinder and cooperates with the first cylinder to form a first transmission hydraulic chamber and a first neutral hydraulic chamber, and the second cylinder is slidably mounted. A spool valve shaft in which a second spool hydraulic pressure chamber and a second spool portion forming a second neutral hydraulic pressure chamber in cooperation with the second cylinder are integrally formed;
The first limp home pressure introduction port that opens to the first cylinder part, the first communication port that communicates with the first neutral hydraulic chamber, the second limp home pressure introduction port that opens to the second cylinder part, and the second neutral hydraulic chamber A second communication port that communicates;
The spool valve shaft is moved to the second shift position by the control hydraulic pressure supplied to the first shift hydraulic chamber, and the spool valve shaft is moved to the first shift position by the control hydraulic pressure supplied to the second shift hydraulic chamber. ,
The limp home pressure introduced from the first limp home pressure introduction port when the spool valve shaft is in the first shift position can be introduced into the first neutral hydraulic chamber via the first communication port, and the second limp home pressure introduction port. Is closed by the second spool part,
A limp home pressure introduced from the second limp home pressure introduction port when the spool valve shaft is in the second shift position can be introduced into the second neutral hydraulic chamber via the second communication port, and the first limp home pressure introduction port. Is closed by the first spool part,
3. The first limp home pressure introduction port is closed by a first spool portion and the second limp home pressure introduction port is closed by a second spool portion when the spool valve shaft is in a neutral position. A hydraulic control device for an automatic transmission according to 1.

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