JP2007040439A - Start control device for automatic manual transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure high start responsiveness of a vehicle to start selecting operation, when starting by switching from a neutral range to a forward range or a reverse range. <P>SOLUTION: A start control device for an automatic manual transmission is provided with a start control means for performing gear selecting control and engaging control of a start clutch when a D range or an R range is selected from the selected state of an N range by dividing a driving transmission path into a plurality of parts. A first clutch CA selected when switching to the R range, and a second clutch CB selected when switching to the D range, are provided as the start clutch. The start control means carries out preshift of selecting a forward start gear stage and a reverse start gear stage selected at the start, prior to range switching under the selection of the N range, and then engages the second clutch CB when switching from the N range to the D range and engages the first clutch CA when switching from the N range to the R range. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention belongs to the technical field of a start control device for an automatic manual transmission in which a drive transmission path is divided into a plurality of parts and a start clutch is provided for each of the plurality of drive transmission paths.

  Conventionally, a plurality of shift speeds are divided into an odd-numbered speed group and an even-numbered speed group, and as a starting clutch, a first clutch that is engaged when an odd-numbered speed group is selected, and a first clutch that is engaged when an even-numbered speed group is selected. A twin-clutch automatic manual transmission including two clutches is known (for example, see Patent Document 1).

In this twin-clutch automatic manual transmission, while the neutral range is selected, all starting clutches are released and all synchronous meshing mechanisms are set to the neutral position (N range: N standby), for example, from the neutral range to the forward gear range. When switching, the forward gear is selected after the range is switched, and then the start clutch including the forward gear is engaged and the forward start is started.
JP 2004-217204 A

  However, in the conventional twin-clutch automatic manual transmission described above, the neutral standby is set while the neutral range is selected. For example, when forward start is intended, after the range is switched, the selection of the forward gear is completed. Since the start clutch engagement is started, there is a problem that the vehicle start responsiveness to the start select operation is lower than a vehicle equipped with an automatic transmission that starts only by the start clutch engagement control. .

  The present invention has been made paying attention to the above problems, and an automatic manual capable of ensuring a high vehicle start responsiveness to a start select operation when starting from a neutral range to a forward range or a reverse range. An object is to provide a transmission start control device.

In order to achieve the above object, in the present invention, the drive transmission path is divided into a plurality of parts, a start clutch is provided for each of the plurality of drive transmission paths, and the forward range or the reverse range is selected from the neutral range selection state. In an automatic manual transmission start control device having start control means for performing gear selection control and start clutch engagement control,
As the starting clutch, a first clutch that is engaged when selecting a gear group that includes a reverse starting gear selected when switching to the reverse range, and a gear that includes a forward starting gear selected when switching to the forward range. A second clutch that is engaged when a group is selected,
The start control means opens the first clutch and the second clutch during the selection of the neutral range, and selects the forward start gear stage and the reverse start gear stage selected at the time of start prior to the range switching. The second clutch is engaged when switching from the neutral range to the forward range, and the first clutch is engaged when switching from the neutral range to the reverse range.

  Therefore, in the start control device for an automatic manual transmission according to the present invention, the start control means opens the first clutch and the second clutch during the selection of the neutral range and selects the front start gear selected at the start. A pre-shift is performed in which the gear and the reverse start gear are selected prior to range switching. When the neutral range is switched to the forward range, the second clutch is engaged to start forward, and when the neutral range is switched to the reverse range, the first clutch is engaged to start backward. That is, when the neutral range is selected, the forward start gear stage and the reverse start gear stage are selected in advance, and when the range is intended to start, starting by torque transmission can be immediately started only by engaging the start clutch. . As a result, when starting from the neutral range to the forward range or the reverse range, it is possible to ensure a high vehicle start response with respect to the start selection operation.

  Hereinafter, the best mode for carrying out a start control device for an automatic manual transmission according to the present invention will be described based on a first embodiment shown in the drawings.

First, the configuration will be described.
FIG. 1 is an overall system diagram showing a twin clutch type automatic manual transmission to which the start control device of Embodiment 1 is applied.
As shown in FIG. 1, the transmission gear train of the twin clutch type automatic manual transmission of the first embodiment includes a transmission case 1, a drive input shaft 2, a first clutch CA (starting clutch), and a second clutch CB. (Starting clutch), torsional damper 3, oil pump 4, first transmission input shaft 5, and second transmission input shaft 6 are provided.

  The first clutch CA is for odd gears (first speed, third speed, fifth speed, reverse), and the second clutch CB is an even gear speed (second speed, fourth speed, sixth speed). ). The drive sides of both clutches CA and CB are connected via a torsional damper 3 to a drive input shaft 2 for inputting a drive force from a drive source such as an engine.

  The driven side of the first clutch CA inputs the driving force from the driving source to the first transmission input shaft 5 when the odd-numbered gear stage is selected. The driven side of the second clutch CB inputs the driving force from the driving source to the second transmission input shaft 6 when the even-numbered gear stage is selected.

  The oil pump 4 is always operated by a drive source. The oil discharged from the oil pump 4 is used as a hydraulic pressure source, and engagement / release control of both clutches CA and CB, which will be described later, and gear position selection control by a shift actuator Execute.

  The second transmission input shaft 6 is a hollow shaft, the first transmission input shaft 5 is a solid shaft, and is connected to the first transmission input shaft 5 via a front needle bearing 7 and a rear needle bearing 8. The second transmission input shaft 6 is rotatably supported in a concentric state.

  The second transmission input shaft 6 is rotatably supported by a ball bearing 9 with respect to the front wall 1 a of the transmission case 1. The first transmission input shaft 5 protrudes from the rear end of the second transmission input shaft 6, and the rear end portion 5 a of the protruding first transmission input shaft 5 passes through the intermediate wall 1 b of the transmission case 1. At the same time, it is rotatably supported by the ball bearing 10 with respect to the intermediate wall 1b.

  The rear end portion 5a of the first transmission input shaft 5 is provided with a transmission output shaft 11 on the same axis. The transmission output shaft 11 is connected to the rear of the transmission case 1 by a tapered roller bearing 12 and an axial bearing 13. While being rotatably supported by the end wall 1c, it is rotatably supported by the rear end portion 5a of the first transmission input shaft 5 via the needle bearing 14.

  A counter shaft 15 is provided in parallel with the first transmission input shaft 5, the second transmission input shaft 6, and the transmission output shaft 11, and this is provided with a transmission case via roller bearings 16, 17 and 18. 1 is rotatably supported by the front end wall 1a, the intermediate wall 1b, and the rear end wall 1c.

  A counter gear 19 is integrally provided at the rear end of the countershaft 15, an output gear 20 is provided on the transmission output shaft 11, and the countershaft 15 and the output gear 20 are meshed with each other to shift the countershaft 15. Drive-coupled to the machine output shaft 11. The counter gear 19 and the output gear 20 constitute a reduction gear set.

  Between the rear end portion 5a of the first transmission input shaft 5 and the countershaft 15, there is a gear group of an odd gear group (first speed, third speed, reverse), that is, in order from the front side. A first speed gear set G1, a reverse gear set GR, and a third speed gear set G3 are arranged.

  The first speed gear set G1 meshes a first speed input gear 21 provided at the rear end portion 5a of the first transmission input shaft 5 and a first speed output gear 22 provided on the counter shaft 15 with each other. Configure together.

  The reverse gear set GR includes a reverse input gear 23 provided at the rear end 5a of the first transmission input shaft 5, a reverse output gear 24 provided on the countershaft 15, and a reverse idler meshing with both gears 23,24. And a gear 25. The reverse idler gear 25 is rotatably supported with respect to a reverse idler shaft 25a that protrudes from the intermediate wall 1b of the transmission case 1.

  The third speed gear set G3 meshes a third speed input gear 26 provided at the rear end 5a of the first transmission input shaft 5 and a third speed output gear 27 provided on the countershaft 15. Configure together.

  A 1-R synchronous mesh mechanism 28 is provided on the countershaft 15 between the first speed gear set G1 and the reverse gear set GR. The first speed output gear 22 is driven to the countershaft 15 by causing the coupling sleeve 28a of the 1-R synchronous meshing mechanism 28 to stroke to the left from the neutral position shown in the figure and to be splined to the clutch gear 28b. The first speed can be selected by combining. Further, the coupling sleeve 28a of the 1-R synchronous meshing mechanism 28 is stroked to the right from the neutral position shown in the drawing, and the clutch gear 28c is spline-fitted to drive-couple the reverse output gear 24 to the countershaft 15. The reverse speed can be selected.

  On the rear end portion 5a of the first transmission input shaft 5 between the third speed gear set G3 and the output gear 20, a 3-5 synchronous meshing mechanism 29 is provided. Then, the third speed input gear 26 is input to the first transmission by causing the coupling sleeve 29a of the 3-5 synchronous mesh mechanism 29 to stroke leftward from the neutral position shown in the figure and to be splined to the clutch gear 29b. Drive-coupled to the shaft 5 allows the third speed to be selected. Further, the coupling sleeve 29a of the 3-5 synchronous meshing mechanism 29 is stroked to the right from the neutral position shown in the drawing, and is spline-fitted to the clutch gear 29c, whereby the first transmission input shaft 5 and the output gear 20 are Is directly connected and the fifth speed can be selected.

  Between the second transmission input shaft 6 and the countershaft 15, a gear set of an even-numbered speed group (second speed, fourth speed, sixth speed), that is, a sixth speed gear in order from the front side. A set G6, a second speed gear set G2, and a fourth speed gear set G4 are arranged.

  The sixth speed gear set G6 is configured by meshing a sixth speed input gear 30 provided on the second transmission input shaft 6 and a sixth speed output gear 31 provided on the countershaft 15.

  The second speed gear set G2 is configured by meshing a second speed input gear 32 provided on the second transmission input shaft 6 and a second speed output gear 33 provided on the countershaft 15.

  The fourth speed gear set G4 is configured by meshing a fourth speed input gear 34 provided on the second transmission input shaft 6 and a fourth speed output gear 35 provided on the countershaft 15.

  A 6-N synchronous meshing mechanism 37 is provided on the counter shaft 15 on the side of the sixth speed gear set G6. Then, the sixth speed output gear 31 is driven to the countershaft 15 by causing the coupling sleeve 37a of the 6-N synchronous meshing mechanism 37 to stroke leftward from the neutral position shown in the drawing and to be splined to the clutch gear 37b. Combined, the 6th speed can be selected.

  A 2-4 synchronous meshing mechanism 38 is provided on the countershaft 15 between the second speed gear set G2 and the fourth speed gear set G4. Then, the second-speed output gear 33 is driven to the countershaft 15 by causing the coupling sleeve 38a of the 2-4 synchronous meshing mechanism 38 to stroke leftward from the neutral position shown in the drawing and to be splined to the clutch gear 38b. Combined, the second speed can be selected. Further, the 4th speed output gear 35 is driven to the countershaft 15 by causing the coupling sleeve 38a of the 2-4 synchronous meshing mechanism 38 to stroke rightward from the neutral position shown in the figure and to be splined to the clutch gear 38c. Combined to enable selection of 4th speed.

  Next, as shown in FIG. 1, as a control system for clutch engagement and gear selection of the twin clutch type automatic manual transmission of the first embodiment, a 3-5 shift fork 41, a 1-R shift fork 42, 6 -N shift fork 43, 2-4 shift fork 44, actuator unit 45, clutch hydraulic module 46, and automatic MT controller 47 are provided.

  The 3-5 shift fork 41 is engaged with the coupling sleeve 29 a of the 3-5 synchronous meshing mechanism 29 and is fixed to the first shift rod 48. The first shift rod 48 is supported so as to be movable in the axial direction with respect to the front end wall 1 a and the intermediate wall 1 b of the transmission case 1. Then, the 3-5 shift bracket 49 is fixed to the first shift rod 48, and the end portion of the 3-5 shift bracket 49 is loosely supported by the spool connecting shaft portion of the 3-5 shift actuator 50. That is, the 3-5 shift fork 41 strokes leftward (when the third speed is selected) or rightward (when the fifth speed is selected) from the illustrated neutral position according to the spool operation of the 3-5 shift actuator 50. .

  The 1-R shift fork 42 is engaged with the coupling sleeve 28a of the 1-R synchronous meshing mechanism 28, and is provided on the second shift rod 51 so as to be capable of stroke in the axial direction. The second shift rod 51 is provided in a fixed state in the axial direction with respect to the front end wall 1 a and the intermediate wall 1 b of the transmission case 1. The end portion of the bracket arm portion 42b that is integrally formed with the bracket cylindrical portion 42a of the 1-R shift fork 42 is idled and supported by the spool connecting shaft portion of the 1-R shift actuator 52. That is, the 1-R shift fork 42 strokes from the neutral position shown in the drawing to the left (when the first speed is selected) or right (when the reverse speed is selected) according to the spool operation of the 1-R shift actuator 52.

  The 6-N shift fork 43 is engaged with the coupling sleeve 37a of the 6-N synchronous meshing mechanism 37, and is provided on the second shift rod 51 which is fixed in the axial direction with respect to the transmission case 1 so as to be able to stroke in the axial direction. . Then, the end portion of the bracket arm portion 43 b formed integrally with the bracket cylindrical portion 43 a of the 6-N shift fork 43 is idled and supported by the spool connecting shaft portion of the 6-N shift actuator 53. That is, the 6-N shift fork 43 strokes from the neutral position shown in the drawing to the left (when the sixth speed is selected) according to the spool operation of the 6-N shift actuator 53.

  The 2-4 shift fork 44 engages with the coupling sleeve 38a of the 2-4 synchronous meshing mechanism 38, and is provided on the second shift rod 51 that is axially fixed with respect to the transmission case 1 so as to be capable of stroke in the axial direction. . The end portion of the bracket arm portion 44b formed integrally with the bracket cylindrical portion 44a of the 2-4 shift fork 44 is loosely supported by the spool connecting shaft portion of the 2-4 shift actuator 54. That is, the 2-4 shift fork 44 strokes from the neutral position shown in the figure to the left (when the second speed is selected) or right (when the fourth speed is selected) according to the spool operation of the 2-4 shift actuator 54. .

  The actuator unit 45 is fixed to a lower position, an upper position, a side position, or the like of the transmission case 1, and includes a 3-5 shift actuator 50, a 1-R shift actuator 52, a 6-N shift actuator 53, 2 -4 shift actuator 54, 3-5 shift position sensor 55, 1-R shift position sensor 56, 6-N shift position sensor 57, 2-4 shift position sensor 58, and actuator hydraulic module 59 This unit has a unit.

  The actuator hydraulic module 59 generates an even gear step pressure Pe and an odd gear step pressure Po based on the line pressure PL adjusted by the clutch hydraulic module 46, and further, each shift actuator according to the selected gear step. Actuator operating pressure is supplied to the transmission pressure oil path to 50, 52, 53, 54.

  The clutch hydraulic module 46 adjusts the line pressure PL based on the oil discharged from the oil pump 4 and also adjusts the clutch control pressure to the first clutch CA based on the even speed step pressure Pe from the actuator hydraulic module 59. The clutch control pressure for the second clutch CB is generated based on the odd speed step pressure Po.

  The automatic MT controller 47 inputs information from a vehicle speed sensor, an accelerator opening sensor, a range position sensor, and other sensors / switches, and outputs a shift stage selection control command to each solenoid of the actuator hydraulic module 59. In addition, a clutch engagement control command (including a line pressure control command) is output to each solenoid of the clutch hydraulic module 46.

  FIG. 2 is a hydraulic circuit diagram showing a sequence solenoid OFF in the actuator hydraulic module 59 and the clutch hydraulic module 46 to which the start control device of the first embodiment is applied, and FIG. 3 is an actuator hydraulic pressure to which the start control device of the first embodiment is applied. FIG. 6 is a hydraulic circuit diagram showing when a sequence solenoid is on in a module 59 and a clutch hydraulic module 46;

  The actuator hydraulic module 59 includes eight oil passages 61, 62, 63, 64, 65, 66, 67, 68 for the four shift actuators 50, 52, 53, 54 and four actuator solenoids 71, 72. , 73, 74 and an actuator hydraulic circuit that is opened and closed by one sequence solenoid 75.

  The eight oil passages are a third speed pressure oil path 61, a fifth speed pressure oil path 62, a first speed pressure oil path 63, a reverse pressure oil path 64, a second speed pressure oil path 65, and a fourth speed pressure. An oil passage 66, a sixth speed oil passage 67, and a neutral pressure oil passage 68 are configured.

  The four actuator solenoids include a first actuator solenoid 71 and a second actuator solenoid 72 that generate the hydraulic pressure of the even gear group, a third actuator solenoid 73 that generates the hydraulic pressure of the odd gear group, and a fourth actuator solenoid. 74.

  As shown in FIG. 2, the one sequence solenoid 75 is a low-speed gear stage (first speed stage, second speed stage, fourth speed stage, reverse stage) including a first speed stage and a reverse stage on the solenoid-off side. ) Can be selected, and as shown in FIG. 3, the first gear and the reverse gear can be selected on the solenoid-on side by selecting a high gear (third speed, fifth speed, sixth speed). A spool 76 that invalidates the selection.

  The actuator hydraulic module 59 includes an even speed step pressure solenoid 77 that generates an even speed step pressure Pe to the first actuator solenoid 71 and the second actuator solenoid 72 based on the line pressure PL generated by the clutch hydraulic module 46, and a clutch. And an odd gear stage pressure solenoid 78 that creates an odd gear stage pressure Po to the third actuator solenoid 73 and the fourth actuator solenoid 74 based on the line pressure PL produced by the hydraulic module 46. Both the shift stage pressure solenoids 77 and 78 are constituted by VBS (variable bleed solenoid).

  The clutch hydraulic module 46 has a line pressure solenoid 85 (line pressure regulating valve) that regulates the line pressure PL based on the oil discharged from the oil pump 4, and the even-numbered gear stage pressure Pe from the actuator hydraulic module 59. A first clutch control pressure solenoid 81 that generates a clutch control pressure for the first clutch CA based on the first clutch CA, and a second clutch control pressure solenoid 82 that generates a clutch control pressure for the second clutch CB based on the odd speed step pressure Po. The first clutch pressure sensor 83 detects the first clutch pressure, and the second clutch pressure sensor 84 detects the second clutch pressure. The line pressure solenoid 85 is configured by a VBS (variable bleed solenoid), and the clutch control pressure solenoids 81 and 82 are configured by a VFS (variable force solenoid).

As shown in FIG. 1, the automatic manual transmission to which the start control device of the first embodiment is applied has a reverse start gear stage selected as a start clutch when switching to a reverse range (hereinafter referred to as “R range”). It is selected at the time of switching to the first clutch CA that is engaged at the time of selection of the odd-numbered speed group including the first speed, the third speed, the fifth speed, and the reverse, and the forward range (hereinafter referred to as “D range”). And a second clutch CB that is engaged when an even-numbered speed group (second speed, fourth speed, and sixth speed) including a forward start gear position is selected.
In the first embodiment, when the D range or the R range is selected from the selection state of the neutral range (hereinafter referred to as “N range”), start control means for performing gear selection control and engagement control of the start clutches CA and CB is provided. I have.

  FIG. 4 is an operation sequence showing a flow of start control executed by the automatic MT controller 47 of the first embodiment, and each step will be described below (start control means).

  The start control means opens the first clutch CA and the second clutch CB during the selection of the N range, and the second gear stage (front start gear stage) and the R gear stage (reverse) selected at the start. Pre-shift is performed to select the starting gear stage prior to range switching, and then the second clutch CB is engaged when switching from the N range to the D range, and the first clutch CA is switched when switching from the N range to the R range. (N range: 2-R standby).

  That is, the engine is started by selecting a parking range (hereinafter referred to as “P range”) (step S1), then the N range is selected (step S2), the third actuator solenoid 73 is turned on, and the reverse speed stage is set. Is selected (step S3), and the second actuator solenoid 72 is turned on to select the second speed stage (step S4). In the time period from the start to the end of the ON operation of the third actuator solenoid 73 and the second actuator solenoid 72, the clutches CA are secured while ensuring the shifting operation of the 1-R shift actuator 52 and the 2-4 shift actuator 54. In order to prevent the generation of transmission torque at CB, keep the line pressure PL from the line pressure solenoid 85 at a pressure (= standby pressure) below the pressure level at which both clutches CA and CB generate transmission torque. Control (step S5).

When the line pressure PL is switched from the N range to the D range (step S6), the line pressure PL from the line pressure solenoid 85 is raised to the normal pressure level (step S7), and the second clutch CB is engaged. (Step S8), the vehicle starts forward (Step S9).
On the other hand, when the line pressure PL is switched from the N range to the R range (step S10), the line pressure PL from the line pressure solenoid 85 is increased to the normal pressure level (step S11), and the first clutch CA is engaged. (Step S12), the vehicle starts moving backward (Step S13).

  Furthermore, after the pre-shift, the start control means switches from the N range to the D range or the R range, and then performs a garage shift that alternately repeats the selection of the D range and the selection of the R range. With the R gear stage still selected, this is handled by switching control of the first clutch CA and the second clutch CB.

That is, when the D range selection is switched to the R range selection (step S14), the second clutch CB is released (step S15), the first clutch CA is engaged (step S16), and the vehicle starts moving backward (step S17).
On the other hand, when the R range selection is switched to the D range selection (step S18), the first clutch CA is released (step S19), the second clutch CB is engaged (step S20), and the vehicle starts moving forward (step S21).

  The start control means prohibits the pre-shift when the line pressure solenoid 85 cannot adjust the pressure due to an abnormality, and sets all of the second speed gear and the R gear to the neutral state.

Next, the operation will be described.
[Shifting action]
It is desirable that the forward start gear stage in the garage shift is as low as possible. However, when applied to a twin-clutch automatic manual transmission like the first embodiment in which the first-speed synchronizer is common to the reverse speed, if the reverse speed is selected by preshift, the first speed cannot be selected. The second speed will be selected. That is, the forward start gear stage is a low speed stage suitable for starting (preferably the first speed which is the lowest speed stage, but the second speed when the first speed synchronizer is common to the reverse speed as in this embodiment). And does not include the middle or high speed stage.

  Therefore, when the garage shift that sets the 2nd-Rth standby while the N range is selected is applied to the twin-clutch automatic manual transmission according to the first embodiment, the vehicle always starts at the 2nd speed when starting forward.

  However, at the time of a normal forward start in which no garage shift operation is performed, the driving force is insufficient if the second speed is maintained as in the case of the garage shift. When the -R synchronous meshing mechanism 28 is switched from the reverse speed to the first speed, and this switching is completed, the shift from the second speed to the first speed is performed by switching control of both clutches CA and CB, and the start is continued at the first speed. Thereafter, as in general shift control, the gears are shifted in the order of 1st speed → 2nd speed → 3rd speed → 4th speed → 5th speed → 6th speed according to the driving state. In this case, the upshift is performed according to the following procedure.

When the first speed is selected, the 1-R shift actuator 52 is controlled to move in the left direction in FIG. 1 to move the coupling sleeve 28a of the synchronous meshing mechanism 28 in the left direction in FIG. The first clutch CA is fastened after drivingly coupled to the shaft 15.
Thus, the drive input from the first clutch CA is axially transmitted by the transmission output shaft 11 via the first transmission input shaft 5 → the first speed gear set G1 → the counter shaft 15 → the output gear sets 19 and 20. Is output and power transmission at the first speed is performed.

When the upshift from the first speed to the second speed is performed, the 2-4 shift actuator 54 is controlled to move leftward in FIG. 1 so that the coupling sleeve 38a of the synchronous meshing mechanism 38 is moved leftward in FIG. The gear 33 is driven and coupled to the countershaft 15, and then the first clutch CA is released and the second clutch CB is engaged (clutch switching) to shift up from the first speed to the second speed. Do.
Thus, the drive input from the second clutch CB is axially transmitted by the transmission output shaft 11 via the second transmission input shaft 6 → second speed gear set G2 → counter shaft 15 → output gear sets 19 and 20. The second power transmission is performed.

At the time of upshifting from the second speed to the third speed, the coupling sleeve 29a of the synchronous meshing mechanism 29 is moved to the left in FIG. 1 by controlling the 3-5 shift actuator 50 to move to the left in FIG. The gear 26 is moved and connected to the first transmission input shaft 5, and then the second clutch CB is released and the first clutch CA is engaged (clutch switching) to change from the first speed to the second speed. Upshift.
Thus, the drive input from the first clutch CA is axially transmitted by the transmission output shaft 11 via the first transmission input shaft 5 → the third speed gear set G3 → the counter shaft 15 → the output gear sets 19 and 20. The third power transmission is performed.

When the upshift from the third speed to the fourth speed is performed, the 2-4 shift actuator 54 is controlled to move rightward in FIG. 1 so that the coupling sleeve 38a of the synchronous meshing mechanism 38 is moved rightward in FIG. The gear 35 is driven and coupled to the countershaft 15, and then the first clutch CA is released and the second clutch CB is engaged (clutch switching) to shift up from the third speed to the fourth speed. Do.
Thus, the drive input from the second clutch CB is axially transmitted by the transmission output shaft 11 via the second transmission input shaft 6 → the fourth speed gear set G4 → the counter shaft 15 → the output gear sets 19 and 20. The fourth power transmission is performed.

At the time of upshifting from the fourth speed to the fifth speed, the coupling sleeve 29a of the synchronous meshing mechanism 29 is moved rightward in FIG. 1 by controlling the 3-5 shift actuator 50 to move rightward in FIG. The first transmission input shaft 5 is directly connected to the transmission output shaft 11 after being moved, and then the second clutch CB is released and the first clutch CA is engaged (clutch switching) to change from the fourth speed to the fifth. Upshift to speed.
As a result, the drive input from the first clutch CA is axially transmitted by the transmission output shaft 11 via the first transmission input shaft 5 → the third speed gear set G3 → the counter shaft 15 → the output gear sets 19 and 20. Is output and power transmission at the fifth speed (speed ratio 1) is performed.

When the upshift from the fifth speed to the sixth speed is performed, the 6-N shift actuator 53 is controlled to move leftward in FIG. 1 so that the coupling sleeve 37a of the synchronous meshing mechanism 37 moves leftward in FIG. The gear 31 is moved and coupled to the countershaft 15, and then the first clutch CA is released and the second clutch CB is engaged (clutch switching) to shift up from the fifth speed to the sixth speed. Do.
Thus, the drive input from the second clutch CB is axially transmitted by the transmission output shaft 11 via the second transmission input shaft 6 → the sixth speed gear set G6 → the counter shaft 15 → the output gear sets 19 and 20. Is output and power transmission at the sixth speed is performed. In addition, when the downshift is sequentially performed from the sixth speed to the first speed, the control opposite to the upshift is performed.

When the R range is selected, the 1-R shift actuator 52 is controlled to move in the right direction in FIG. 1 to move the coupling sleeve 28a of the synchronous meshing mechanism 28 in the right direction in FIG. The drive shaft is coupled to the countershaft 15, and then the first clutch CA is engaged.
As a result, the drive input from the first clutch CA is output in the axial direction by the transmission output shaft 11 via the first transmission input shaft 5 → the reverse gear set GR → the counter shaft 15 → the output gear sets 19 and 20. Then, reverse speed power transmission is performed.

[Start control action in garage shift]
Conventionally, in the twin-clutch automatic manual transmission, as shown in FIG. 5, the engine is started by selecting the P range (step S101), and then the N range is selected (step S102). At the same time, the neutral standby is performed with all the synchronous meshing mechanisms in the neutral position.

When the range is switched from the N range to the D range (step S103), the fourth actuator solenoid 74 is turned on to select the first speed (step S104), the first clutch CA is engaged (step S105), and the vehicle starts moving forward. (Step S106).
On the other hand, when the N range is switched to the R range (step S107), the third actuator solenoid 73 is turned on to select the reverse gear (step S108), the first clutch CA is engaged (step S109), and the vehicle starts to reverse (step S109). Step S110).

Further, after switching from the N range to the D range by garage shift, when the R range is selected (step S111), the first clutch CA is released (step S112), the third actuator solenoid 73 is turned on, and the first speed pressure is set. And the neutral state is established (step S113), the third actuator solenoid 73 is kept on to select the R speed (step S114), the first clutch CA is engaged (step S116), and the vehicle starts moving backward.
On the other hand, when the D range is selected after switching from the N range to the R range by garage shift (step S117), the first clutch CA is released (step S118) and the fourth actuator solenoid 74 is turned on to release the reverse pressure. The neutral state is set (step S119), the fourth actuator solenoid 74 is kept on to select the first speed (step S120), the first clutch CA is engaged (step S121), and the vehicle starts moving forward.

  Therefore, in the conventional twin-clutch automatic manual transmission, since N standby is performed while the N range is selected, as shown in FIG. 6, for example, when a reverse start is intended, the N range is switched to the R range. After that, since the procedure of waiting for the selection of the R-speed gear to be completed and starting the engagement of the first clutch CA is performed, it takes from the time of the N → R selection operation until the transmission torque is generated and the vehicle starts. Compared with a vehicle equipped with an automatic transmission that starts only by engagement control of the start clutch, the vehicle has a low start response to the start select operation.

  Further, in the case of a garage shift to switch to the D range after starting in the R range, as shown in FIG. 6, the first clutch CA is released, the fourth actuator solenoid 74 is turned on, the reverse pressure is released, and the neutral state is established. Since it is performed by sequential control that the actuator solenoid 74 is kept on and the first speed is selected and the first clutch CA that has been released is engaged, the time required from reverse to forward start becomes longer, and the garage shift Vehicle start response to operation is low.

  On the other hand, in the start control device for the automatic manual transmission according to the first embodiment, the start selection is performed by switching from the N range to the D range or the R range by setting the second speed-R speed standby while the N range is selected. It is intended to ensure a high vehicle start response to the operation.

  That is, when the shift lever is switched from P to N, in the operation sequence of FIG. 4, the process proceeds from step S1, step S2, step S3, step S4, and step S5. That is, during selection of the N range from step S2 to step S5, the reverse gear is selected in step S3, the second gear is selected in step S4, and the 1-R shift actuators 52 and 2-4 are selected in step S5. During the shift operation of the shift actuator 54, the line pressure PL is controlled so as to keep the standby pressure. When the shift lever is switched from N to R, in the operation sequence of FIG. 4, the process proceeds from step S5 to step S10 → step S11 → step S12 → step S13. The line pressure PL is increased to the normal pressure level, the first clutch CA is engaged in step S12, and the vehicle starts to reverse in step S13.

  Furthermore, when the garage shift is performed such that the D range is selected after switching to the R range, the first clutch CA and the second clutch CB are switched while the second speed gear stage and the R gear stage are selected. Responded by control. That is, when the D range is selected from PNR, in the operation sequence of FIG. 4, the process proceeds from step S13 to step S18 → step S19 → step S20 → step S21, and the first clutch CA is released in step S19. In step S20, the second clutch CB is engaged, and in step S21, the vehicle starts moving forward.

By the way, Figure 7 shows the shift lever range position, R speed pressure, 2nd speed pressure, line pressure, 1st clutch when garage shift is performed after switching from N range to R range and starting from R range to D range. It is a time chart which shows engagement / release of CA and engagement / release of the second clutch CB.
When the P range is switched to the N range at time t0, the line pressure PL is increased to a pressure equal to or lower than the standby pressure, the R speed pressure is applied from time t0, and the second speed pressure is increased at time t1 when the R speed pressure is increased. In addition, the R speed pressure and the 2nd speed pressure increase at time t2, and the line pressure PL is set to the drain pressure at time t3 immediately after the two gears are selected. When the switching operation from the N range to the R range is performed at time t4, the line pressure PL is immediately increased from time t4, and the engagement of the first clutch CA is started with the second clutch CB open. The When the line pressure PL rises to the normal pressure at time t5, and when the engagement pressure of the first clutch CA rises to a level at which start torque is generated at time t6, reverse start is started. That is, the response delay time of the backward start with respect to the switching operation from the N range to the R range is a short time from the time t4 to the time t6.

  Thereafter, when the switching operation from the R range to the D range is performed at time t7, the switching control by opening the first clutch CA and engaging the second clutch CB is started at a timing slightly delayed from time t7. . When the engagement pressure of the first clutch CA becomes equal to or lower than the level at which the start torque is generated at time t8, the process waits until the engagement pressure of the second clutch CB becomes a level at which the start torque is generated. When the engagement pressure of the clutch CB rises to a level that generates a starting torque, the clutch CB moves forward. That is, the response delay time of the forward start with respect to the garage shift operation from the R range to the D range is a short time from the time t8 to the time t9.

As described above, in the start control device of the first embodiment, the first clutch CA is selected at the time of range switching intended for start-up by pre-shift standby in which the second speed stage and the R gear stage are selected in advance while the N range is selected. Alternatively, it is possible to start immediately by torque transmission only by engaging the second clutch CB.
Therefore, when starting after switching from the N range to the R range, as shown in FIG. 7, it is possible to ensure a high start response of the vehicle with respect to the start selection operation. Similarly, at the time of starting after switching from the N range to the D range, it is possible to ensure a high vehicle start response with respect to the start selection operation.

In addition, a garage shift in which the D range selection and the R range selection are repeated after the start can be dealt with only by the switching control of the first clutch CA and the second clutch CB.
Therefore, as shown in FIG. 7, it is possible to perform forward start and reverse start with good response to the range position switching operation only by the switching control of the first clutch CA and the second clutch CB.

  In addition, while the N range is selected, control is performed to keep the line pressure PL low. For example, even when the first clutch control solenoid 81 or the second clutch control solenoid 82 is in an open failure state. Even if the line pressure PL adjusted to the first clutch CA or the second clutch CB is supplied as it is, the transmission torque at a level at which the vehicle can start cannot be generated, and the vehicle jumps out while the N range is selected. Can be prevented.

Next, the effect will be described.
In the start control device for the automatic manual transmission of the first embodiment, the following effects can be obtained.

  (1) The drive transmission path is divided into a plurality of parts, and a start clutch is provided for each of the plurality of drive transmission paths. When the D range or the R range is selected from the selected state of the N range, the gear selection control and the start clutch are engaged. In a start control device for an automatic manual transmission provided with a start control means for performing control, a first clutch that is engaged when the odd-number shift stage group including a reverse start gear stage that is selected when switching to the R range is selected as the start clutch. CA and a second clutch CB that is engaged when an even-numbered gear group including a forward start gear selected when switching to the D range is selected, and the start control means is configured to select the N range when the N range is selected. The first clutch CA and the second clutch CB are opened, and the range of the forward start gear stage and the reverse start gear stage selected at the start is switched. The pre-shift to be selected in advance is executed, and then the second clutch CB is engaged when switching from the N range to the D range, and the first clutch CA is engaged when switching from the N range to the R range. When starting after switching to the D range or the R range, it is possible to ensure a high vehicle start response with respect to the start select operation.

  (2) After the pre-shift, the start control means switches from the N range to the D range or the R range, and then performs a garage shift that alternately repeats the selection of the D range and the selection of the R range. In order to respond by switching control of the first clutch CA and the second clutch CB while selecting the reverse start gear stage, the forward start and the reverse start are responsive to the garage shift operation that repeats the D range selection and the R range selection. It can be performed.

  (3) The start clutches CA and CB are clutches that are fastened based on a line pressure PL controlled by a line pressure solenoid 85, and the start control means is configured so that the start control means In order to keep the line pressure PL above the pressure required to select the forward start gear stage and the reverse start gear stage and below the pressure level at which the start clutches CA and CB generate transmission torque, the N range is being selected. While securing a pre-shift for selecting the forward start gear stage and the reverse start gear stage, even when the control solenoid for generating the control pressure of the start clutches CA and CB is open, it is possible to prevent the vehicle from popping out.

  (4) When the start control means is switched from the N range where the line pressure PL is kept low to the D range or the R range, the line pressure PL from the line pressure solenoid 85 is raised, and then the clutch pressure adjusting valve This increases the clutch pressure to the starting clutches CA and CB, so that the starting clutch CA or CB is not fastened at a steep slope than the rising slope of the line pressure PL, and the starting shock is kept low. Can do.

  (5) When the line pressure solenoid 85 cannot regulate pressure due to an abnormality, the start control means prohibits the pre-shift and sets all of the forward gear and the reverse gear to the neutral state. At this time, it is possible to reliably prevent the vehicle from jumping out in the N range.

  The automatic manual transmission start control device of the present invention has been described based on the first embodiment, but the specific configuration is not limited to the first embodiment, and each claim of the claims Design changes and additions are allowed without departing from the gist of the invention.

  In the first embodiment, a hydraulic clutch or shift actuator is shown as the start clutch or shift actuator, and the line pressure is kept low during the selection of the N range as the start control means. Or an electromagnetic or motor actuator may be used as the shift actuator. In this case, while the N range is selected, the clutch drive circuit may be forcibly cut off or the current may be limited. In short, as the start control means, while the neutral range is selected, the first clutch and the second clutch are opened, and the forward start gear stage and the reverse start gear stage selected at the start are selected prior to the range switching. The first clutch is not limited to the first embodiment as long as the second clutch is engaged at the time of switching from the neutral range to the forward range and the first clutch is engaged at the time of switching from the neutral range to the reverse range.

  In the first embodiment, the start control device is applied to a twin-clutch automatic manual transmission. However, if the automatic manual transmission includes a plurality of start clutches, the automatic manual transmission including three or more clutches is used. Can also be applied. In short, the drive transmission path is divided into a plurality of parts, and a start clutch is provided for each of the plurality of drive transmission paths. When the forward range or reverse range is selected from the neutral range selection state, the gear selection control and the start clutch engagement control are performed. It can be applied to an automatic manual transmission equipped with a start control means for performing

1 is an overall system diagram showing a twin clutch type automatic manual transmission to which a start control device of Embodiment 1 is applied. FIG. 3 is a hydraulic circuit diagram illustrating a sequence solenoid OFF in the actuator hydraulic module and the clutch hydraulic module to which the start control device of the first embodiment is applied. FIG. 3 is a hydraulic circuit diagram showing a sequence solenoid ON in the actuator hydraulic module and the clutch hydraulic module to which the start control device of the first embodiment is applied. 3 is an operation sequence showing a flow of a start control process executed by the automatic MT controller according to the first embodiment. It is an operation | movement sequence which shows the flow of the start control process performed with the automatic MT controller of a prior art example. Shift lever range position, R speed pressure, 1st speed pressure, line pressure, 1st clutch CA when a garage shift is performed after switching from N range to R range in a conventional system and then starting from R range to D range It is a time chart which shows the fastening / release of. Shift lever range position, R speed pressure, 2nd speed pressure, line pressure, No. 1 when garage shift is performed by switching from N range to R range in the system of Example 1 and then starting from R range to D range It is a time chart which shows engagement / release of 1 clutch CA and engagement / release of 2nd clutch CB.

Explanation of symbols

CA 1st clutch (starting clutch)
CB 2nd clutch (starting clutch)
G1 1st gear set
G2 2nd gear set
G3 3rd speed gear set
G4 4th gear set
G6 6th gear set
GR reverse gear set 28 1-R synchronous meshing mechanism 29 3-5 synchronous meshing mechanism 37 6-N synchronous meshing mechanism 38 2-4 synchronous meshing mechanism 41 3-5 shift fork 42 1-R shift fork 43 6-N shift fork 44 2-4 shift fork 45 actuator unit 46 clutch hydraulic module 47 automatic MT controller 48 first shift rod 49 3-5 shift bracket 50 3-5 shift actuator 51 second shift rod 52 1-R shift actuator 53 6-N shift Actuator 54 2-4 Shift Actuator 55 3-5 Shift Position Sensor 56 1-R Shift Position Sensor 57 6-N Shift Position Sensor 58 2-4 Shift Position Sensor 59 Actuator Hydraulic Module 61 3rd Speed Pressure Oil Path 62 5th Speed Pressure Oil Road 63 1st speed oil path 64 Reverse Oil path 65 Second speed pressure oil path 66 Fourth speed pressure oil path 67 Sixth speed pressure oil path 68 Neutral pressure oil path 71 First actuator solenoid 72 Second actuator solenoid 73 Third actuator solenoid 74 Fourth actuator solenoid 75 Sequence solenoid 76 Spool 77 Even speed step pressure solenoid 78 Odd speed step pressure solenoid 81 First clutch control pressure solenoid 82 Second clutch control pressure solenoid 83 First clutch pressure sensor 84 Second clutch pressure sensor 85 Line pressure solenoid (line pressure regulating valve)

Claims (5)

The drive transmission path is divided into a plurality of parts, and a start clutch is provided for each of the plurality of drive transmission paths. When the forward range or the reverse range is selected from the neutral range selection state, the gear selection control and the start clutch engagement control are performed. In a start control device for an automatic manual transmission having a start control means,
As the starting clutch, a first clutch that is engaged when selecting a gear group that includes a reverse starting gear selected when switching to the reverse range, and a gear that includes a forward starting gear selected when switching to the forward range. A second clutch that is engaged when a group is selected,
The start control means opens the first clutch and the second clutch during the selection of the neutral range, and selects the forward start gear stage and the reverse start gear stage selected at the time of start prior to the range switching. Control of the automatic manual transmission, wherein the second clutch is engaged when switching from the neutral range to the forward range, and the first clutch is engaged when switching from the neutral range to the reverse range. apparatus. In the automatic manual transmission start control device according to claim 1,
After the pre-shift, the start control means switches from the neutral range to the forward range or the reverse range, and then performs a garage shift that alternately repeats the forward range selection and the reverse range selection. A start control device for an automatic manual transmission, which responds by switching control of the first clutch and the second clutch while the gear stage is selected. In the automatic manual transmission start control device according to claim 1 or 2,
The starting clutch is a clutch that is fastened based on a line pressure controlled by a line pressure regulating valve,
When the neutral range is selected, the start control means generates a transmission torque when the line pressure from the line pressure regulating valve exceeds the pressure required to select the forward start gear stage and the reverse start gear stage. An automatic manual transmission start control device characterized by keeping the pressure level below. In the automatic manual transmission start control device according to claim 3,
When the start control means is switched from the neural range in which the line pressure is kept low to the forward range or the reverse range, after the line pressure from the line pressure regulating valve is increased, the clutch control valve adjusts the start clutch. An automatic manual transmission start control device characterized by increasing the clutch pressure. In the automatic manual transmission start control device according to claim 3 or 4,
The starting control means prohibits the pre-shift when the line pressure regulating valve cannot be regulated due to an abnormality, and sets all of the forward gear and the reverse gear to a neutral state. apparatus.

Images