JP2019211086A - Vehicular transmission device - Google Patents

Abstract

To provide a vehicular transmission device that has a simple structure, is capable of performing smooth gear shifting, and makes it possible to easily perform the maintenance work of a counter brake mechanism.SOLUTION: A vehicular transmission device comprises: a main shaft 22 and a counter shaft 23, which are supported on a transmission case 10; a plurality of transmission gear pairs supported by these shafts; sleeves 51b, 52b that engage with and disengage from either of main gears 31 to 34 integrally in the rotation direction; and a counter brake mechanism 70 that can reduce the speed of the counter shaft 23, and the vehicular transmission device changes the speed of an input from the front end side of the transmission case 10 and outputs the same from the rear end side. The counter brake mechanism 70 is disposed on the rear end side of the transmission case 10, and includes a brake shaft 79 that is connected to the counter shaft 23 and is rotatably supported on the case 10, and a brake unit 72U that can be coupled by a spline to the rear end part of the brake shaft.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a vehicle transmission.

  2. Description of the Related Art Conventionally, as a transmission for a vehicle, a parallel-shaft gear type that supports in parallel a main shaft that supports a plurality of main gears so that the main gear can idle and a counter shaft that has a plurality of counter gears that are always meshed with the main gear. Things are used a lot.

  In this type of vehicle transmission, the main gear side spline and the sleeve side spline supported by the main shaft so as to be movable in the axial direction are engaged with each other, thereby transmitting power between the main gear and the main shaft of the required shift stage. It is designed to be combined as possible.

  In general, the rotation of the main gear and the main shaft is synchronized in order to suppress gear noise when the main gear and the sleeve spline are engaged.

  As a synchronization method, a synchronous meshing mechanism having a synchronizer ring is generally used, but recently, a countershaft rotating speed that can be directly controlled by a counterbrake mechanism has been proposed. .

  For example, a multi-plate counter brake mechanism is arranged on the transmission input shaft side with respect to the counter shaft, and the operating pressure of the counter brake mechanism changes to high or low depending on whether or not the difference in rotational speed between the main gear and the sleeve corresponding to the predetermined value or more. What is to be known is known.

  Further, it is known that an oil passage is formed in a counter brake mechanism piston, a hub for holding a friction plate, etc., so that the counter brake mechanism can be made compact while ensuring lubrication and cooling performance.

  Such a vehicle transmission device has an advantage that smooth synchronization and meshing at the time of shifting can be achieved while synchronizer ring is omitted to reduce cost by simplifying the structure.

JP 2001-280432 A JP 2001-263457 A

  However, in the conventional vehicle transmission as described above, the counter brake mechanism is disposed in the closed space on the front end side of the transmission case coupled to the engine side. That is, the counter brake mechanism is disposed inside a case portion (hereinafter referred to as a clutch case) that houses the clutch device on the front end side of the transmission case.

  Therefore, when it is necessary to perform maintenance work for the counter brake mechanism, another large-scale work for releasing the fastening of the large-diameter portion of the transmission case fastened to the engine side or removing the vehicle transmission from the vehicle. As a result, the maintenance work of the counter brake mechanism cannot be facilitated.

  The present invention has been made in order to solve the above-described conventional problems, and has a simple structure and can perform a smooth gear shift, and can easily perform a maintenance work for a counter brake mechanism. The purpose is to provide.

  To achieve the above object, a vehicle transmission according to the present invention is supported by a transmission case, a main shaft and a counter shaft that are rotatably supported by the transmission case in parallel with each other, and are rotatably supported by the main shaft. A plurality of transmission gear pairs including a plurality of main gears and a plurality of counter gears supported by the counter shaft so as to always mesh with the main gears, and a corresponding main gear among the main gears integrally engaged in the rotation direction And a sleeve movable in the axial direction so as to be disengaged, and a counter brake mechanism capable of outputting a braking force to the counter shaft, and when the sleeve is integrally engaged with the corresponding main gear in the rotational direction, Front end side of the transmission case A transmission for a vehicle that shifts input rotational power and outputs rotational power after shifting from the rear end side of the transmission case, wherein the counter brake mechanism is disposed on the rear end side of the transmission case. It is characterized by that.

  In the vehicle transmission device of the present invention, the counter brake mechanism includes a brake case supported on the rear end side of the transmission case, and a brake cover detachably supported on the brake case. be able to.

  An auxiliary transmission that further shifts the rotational power after the shift output from the rear end side of the main shaft; an auxiliary transmission case that houses the auxiliary transmission on the rear end side of the transmission case; The brake case of the counter brake mechanism may be supported by the auxiliary transmission case.

  In the vehicle transmission of the present invention, the counter brake mechanism has a front end portion integrally connected to the counter shaft in the rotation direction and a rear end portion formed with a spline, and is rotatably supported by the transmission case. And a brake unit that can be splined to the rear end of the brake shaft.

  In this case, the brake unit may house the fixed and movable friction plates and the brake piston that presses both the friction plates in the brake cover.

  According to the present invention, the structure of the vehicle transmission device is simple and smooth, and in addition to enabling maintenance work from the outside of the rear end side of the transmission case with respect to the counter brake mechanism, the transmission case Therefore, it is possible to provide a vehicular transmission that can eliminate the large-scale operation of releasing the fastening of the large-diameter portion or removing the vehicular transmission from the vehicle, and facilitate the maintenance work of the counter brake mechanism.

1 is a longitudinal sectional view of a vehicle transmission device according to an embodiment of the present invention. It is the elements on larger scale which expanded the part enclosed with the dashed-two dotted line in FIG. 1 is a longitudinal sectional view of a main part of a counter brake mechanism in a vehicle transmission apparatus according to an embodiment of the present invention. It is a skeleton figure of the transmission for vehicles concerning one embodiment of the present invention. FIG. 5 is an operation explanatory diagram of a counter brake mechanism in the vehicle transmission device according to the embodiment of the present invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  FIG. 1 is a longitudinal sectional view of a vehicle transmission apparatus according to an embodiment of the present invention, and FIG. 4 shows a skeleton diagram thereof.

  First, the configuration will be described.

  As shown in FIGS. 1 and 4, the vehicle transmission device 2 of the present embodiment is disposed behind the engine 1 that is a power source, and includes a transmission case 10 and a parallel shaft provided in the transmission case 10. A gear transmission 20 and an auxiliary transmission 80 provided at the rear stage of the parallel-shaft gear transmission 20 and capable of two-step high / low speed shifting are provided. Here, the parallel shaft gear transmission 20 with a splitter is used as the main transmission, and is separated from the auxiliary transmission 80 at the subsequent stage. Further, a splitter may not be provided.

  A transmission case 10 includes a left-side clutch case 11, a center-side main case 12, and a right-side auxiliary transmission case 13 in FIG. The positioning pins 10a and 10b and a plurality of fastening bolts are integrally connected to each other.

  The clutch case 11 is fastened to an engine side member 5 such as a flywheel housing fastened to the rear portion or the rear portion of the engine 1 on the front end side which is the left end side in FIG.

  The clutch case 11 has a partition wall portion 11 b that closes the opening on the front end side of the main case 12 on the rear end side coupled to the main case 12. A known clutch device 3 and flywheel 4 are housed in the clutch case 11 closed by the engine 1 and the engine-side member 5, and each sliding portion and meshing portion in the vehicle transmission device 2 are accommodated. A mechanical oil pump 6 that pumps oil for lubrication / cooling is supported by the partition wall 11b.

  A parallel shaft gear transmission 20 is accommodated in the main case 12, and an auxiliary transmission 80 is accommodated in the auxiliary transmission case 13.

  The parallel-shaft gear transmission 20 includes an input shaft 21 that inputs rotational power from the engine 1 via the clutch device 3 on the front end side of the transmission case 10, a main shaft 22 that can input rotational power from the input shaft 21, and Counter shaft 23. The input shaft 21 protrudes into the clutch case 11 while being supported by the partition wall 11 b of the clutch case 11 via the bearing 18, and is splined to the clutch device 3.

  The main shaft 22 is disposed on the same axis with respect to the input shaft 21, and is supported on the front end side of the input shaft 21 via the bearing 16 by the concave portion of the rear end portion of the input shaft 21, while the main shaft 22 is connected via the bearing 17. It is supported by a partition wall portion 12b located on the rear end side of the case 12. The rear end portion of the main shaft 22 protrudes rearward from the partition wall portion 12b so that the rotational power after shifting by the parallel shaft gear transmission 20 can be output to the rear end side of the transmission case 10.

  The counter shaft 23 is disposed so as to be separated from the main shaft 22 in parallel, and is supported by the clutch case 11 and the main case 12 via bearings 27 and 28. That is, the main shaft 22 and the counter shaft 23 are parallel axes that are supported in parallel with each other and rotatably with respect to the transmission case 10. Further, the input shaft of the oil pump 6 is integrally coupled to the front end portion of the counter shaft 23 in the rotation direction, and the discharge amount of the oil pump 6 changes according to the rotation speed of the counter shaft 23. Yes.

  A plurality of main gears 31, 32, 33, 34 for shifting are supported on the main shaft 22 so as to be idle, and a splitter high gear 35 is supported on the input shaft 21 so as to be idle. On the other hand, the counter shaft 23 integrally supports a plurality of counter gears 41, 42, 43, 44, 45 that are always meshed with the main gears 31 to 34 and the splitter high gear 35. These counter gears 41 to 45 are formed integrally with the counter shaft 23 here, but may be separate parts supported by the counter shaft 23 so as to be integrally rotatable.

  The main shaft 22 further branches into a plurality of radial oil holes while penetrating the central portion in the axial direction, and the oil pumped from the oil pump 6 is supplied to the inner peripheral portions and meshing portions of the main gears 31 to 34. An oil passage 22h to be supplied is formed.

  As shown in FIG. 4, the plurality of main gears 31 to 34 and the plurality of counter gears 41 to 44 that mesh with each other include a first speed transmission gear pair 36, a second speed transmission gear pair 37, a third speed transmission gear pair 38, and A plurality of speed change gear pairs 36 to 39 each having a reverse gear ratio 39 and having a different gear ratio are configured.

  Of course, the transmission gear ratio of the first-speed transmission gear pair 36 is larger than the transmission gear ratio of the second-speed transmission gear pair 37, and the transmission gear ratio of the second-speed transmission gear pair 37 is that of the third-speed transmission gear pair 38. It is set larger than the transmission gear ratio. An idle gear 46 is interposed between the main gear 34 and the counter gear 44 of the reverse speed transmission gear pair 39.

  The splitter high gear 35 and the counter gear 45 constitute a splitter high gear pair 40H that shifts while inputting rotational power from the input shaft 21 when the splitter high gear 35 is coupled to the input shaft 21. The main gear 33 and the counter gear 43 constitute a splitter low gear pair 40 </ b> L that changes speed while inputting rotational power from the input shaft 21 when the main gear 33 is coupled to the input shaft 21. That is, the main gear 33 also serves as a splitter low gear.

  Specifically, for example, the splitter high gear 35 has a smaller number of teeth than the counter gear 45, and the splitter high gear pair 40H decelerates while inputting the rotation from the input shaft 21. Similarly, the main gear 33 has fewer teeth than the counter gear 43, and the splitter low gear pair 40L is decelerated while inputting rotation from the input shaft 21. The transmission gear ratio of the splitter low gear pair 40L is larger than the transmission gear ratio of the splitter high gear pair 40H.

  A plurality of sleeves are located between the main gears 31 to 34 and the splitter high gear 35 arranged at predetermined intervals on the rotation center axis of the input shaft 21 and the main shaft 22 so as to be positioned within the axial distance therebetween. The type mesh switching mechanisms 51, 52, 53 are arranged.

  In addition, dog-shaped splines 31a, 32a, 33a, 33b, 34a, and 35a for meshing switching, which will be described later, are integrally mounted on the plurality of main gears 31 to 34, the splitter low gear 33, and the splitter high gear 35, respectively. ing. Here, when the main gear 33 functions as a splitter low gear instead of a third-speed main gear, the splitter low gear 33 is used (hereinafter the same).

  The mesh switching mechanism 51 is disposed between the main gear 31 of the first-speed transmission gear pair 36 and the main gear 34 of the reverse-speed transmission gear pair 39. The mesh switching mechanism 52 is disposed between the main gear 32 of the second speed transmission gear pair 37 and the main gear 33 of the third speed transmission gear pair 38. The mesh switching mechanism 53 is disposed between a splitter low gear 33 that is a part of the splitter low gear pair 40L and a splitter high gear 35 that is a part of the splitter high gear pair 40H.

  Each of the mesh switching mechanisms 51 and 52 does not have an intermediate part for generating friction torque for rotation synchronization such as a synchronizer ring. On the other hand, the mesh switching mechanism 53 has a friction taper surface for synchronizer ring or rotation synchronization, similarly to a known synchronous mesh mechanism.

  Specifically, the mesh switching mechanism 51 includes a hub 51a that is spline-coupled to the main shaft 22, a sleeve 51b that has an annular groove on the outer peripheral side and spline teeth that are spline-coupled to the hub 51a on the inner peripheral side, And a detent mechanism for urging the sleeve 51b to the neutral position.

  The sleeve 51b of the meshing switching mechanism 51 is movable in the axial direction with respect to the main shaft 22 by spline coupling to the hub 51a, and the splines 31a, 34a of the corresponding first gear and reverse gear main gears 31, 34 are movable. Any one of them can be integrally engaged and disengaged in the rotational direction.

  The sleeve 51b is moved in the axial direction by the first shift fork 61 that engages with the annular groove on the outer peripheral side. When the shift operation is not performed, the sleeve 51b is returned to the neutral position and then the neutral position by the detent mechanism. Is supposed to be retained.

  The first shift fork 61 is selectively selected (selected) by the known shift / select mechanism 60 shown in FIG. It is supported by.

  When the first shift shaft 66 is operated for shifting, the first shift fork 61 is configured so that any one of the spline teeth of the sleeve 51b corresponds to the shift operation among the splines 31a and 34a of the corresponding main gears 31 and 34. Can be moved axially to the side.

  The spline teeth portion of the internal teeth of the sleeve 51b and the spline teeth 31a and 34a of the external teeth of the main gears 31 and 34 respectively have dog-tooth chamfer portions. For example, the spline teeth portion of the sleeve 51b and the splines of the main gear 31 By engaging the chamfer portion 31a, the meshing operation can be started in a rotation-synchronized state and can be advanced to the completion of meshing.

  Substantially similar to the mesh switching mechanism 51, the mesh switching mechanisms 52 and 53 have hubs 52a and 53a spline-coupled to the main shaft 22, and annular grooves on the outer peripheral side and spline-coupled to the hubs 52a and 53a on the inner peripheral side. And sleeves 52b and 53b having spline teeth portions and detent mechanisms for urging the sleeves 52b and 53b to the neutral position.

  The sleeve 52b of the mesh switching mechanism 52 is movable in the axial direction with respect to the main shaft 22 by spline coupling to the hub 52a, and the splines 32a and 33a of the corresponding second and third speed main gears 32 and 33 are provided. Any one of them can be integrally engaged and disengaged in the rotational direction.

  The sleeve 52b is moved in the axial direction by the second shift fork 62 that engages with the annular groove on the outer peripheral side. When the shift operation is not performed, the sleeve 52b is returned to the neutral position and then the neutral position by the detent mechanism. Is supposed to be retained.

  Further, the sleeve 53b of the meshing switching mechanism 53 can be moved in the axial direction with respect to the input shaft 21 and the main shaft 22 by spline coupling to the hub 53a, and any of the corresponding splitter low gear 33 and splitter high gear 35 can be freely moved. One of them can be engaged and disengaged integrally in the rotational direction.

  The sleeve 53b is split between the input shaft 21 and the counter shaft 23 when the third shift fork 63 engaged with the annular groove on the outer peripheral side is moved from the neutral position to one side or the other side in the axial direction. Either the low gear 33 or the splitter high gear 35 is selected and interposed. Further, when the sleeve 53b is returned to the neutral position, the sleeve 53b is held at the neutral position by the above-described detent mechanism.

  The second and third shift forks 62, 63 are respectively connected to the second and third shift shafts 67, 68 among the shift shafts 66, 67, 68 that are selectively shifted by the shift / select mechanism 60. It is supported. When the second shift shaft 67 is operated to shift, the second shift fork 62 changes the spline tooth portion of the sleeve 52b according to the shift operation among the splines 32a and 33a of the second gear and the third gear 32, 33. Further, it can be moved in the axial direction so as to mesh with any one side. Further, when the third shift shaft 68 is operated to shift, the third shift fork 63 uses the spline tooth portion of the sleeve 53b as an arbitrary one according to the shift operation among the splines 33b and 35a of the splitter low gear 33 and the splitter high gear 35. It can be moved in the axial direction so as to be meshed with one side.

  The shift / select mechanism 60 and its upstream operation mechanism will not be described in detail. For example, the lever position when the driver inputs an operation to a shift lever (gear change lever) (not shown) is detected by a sensor, and a gear change request is met. The auxiliary operation force that assists the operation input to the shift lever is output by a pneumatic power shift mechanism that uses the pressure of compressed air from the pressure accumulation tank P, and the shift / shift is compared with the light operation force to the shift lever. The select mechanism 60 is operated with a sufficiently large operating force.

  The vehicle of this embodiment is equipped with a shift control ECU (electronic control unit) that controls the operation input to the shift / select mechanism 60 based on not only the shift lever position but also the vehicle speed, the accelerator position, and the like. By operating the electromagnetic switching valve V, the fluid pressure control valve, the motor or other electric actuator in accordance with the shift request from the ECU, the operation force required for the shift operation required for the shift / select mechanism 60 is obtained. It is input from these actuators.

  That is, in the vehicle transmission device 2, the operation input to the shift / select mechanism 60 is controlled by the ECU, so that the parallel shaft gear transmission 20 having the same configuration as the manual transmission can respond to the vehicle speed, acceleration request, and the like. Thus, automatic transmission control is possible.

  In the parallel shaft gear transmission 20, mesh switching mechanisms 51, 52, and 53 that exhibit the function of the synchronous meshing mechanism in combination with the synchronous control of shaft rotation described later according to the operation input to the shift lever described above. Operated.

  For example, when any one of the mesh switching mechanisms 51 and 52 is operated, the counter shaft 23 is connected to any one of the first-speed transmission gear pair 36, the second-speed transmission gear pair 37, and the third-speed transmission gear pair 38. Whether the rotational power is transmitted to the main shaft 22 or whether the rotational power is reversed and transmitted from the counter shaft 23 to the main shaft 22 via the reverse gear pair 39 and the idle gear 46. It is done. Then, the rotational power after the shift is output from the rear end side of the main shaft 22.

  When the mesh switching mechanism 53 is operated, rotational power input from the engine 1 to the parallel shaft gear transmission 20 via the clutch device 3 is transmitted from the input shaft 21 to the splitter high gear pair 40H, or splitter low gear. Whether it is transmitted to the pair 40L is switched. Accordingly, in the parallel shaft gear transmission 20, it is possible to perform two-step shift by the high and low pairs of the splitter high gear 40H and the splitter low gear pair 40L and three steps of the first to third gear pairs 36 to 38. The vehicle transmission device 2 as a whole is capable of shifting forward 12 speeds and reverse 2 speeds by combining with the high and low 2 speed shifting by the auxiliary transmission 80.

  An outer gear-shaped sun gear 81 that is an input shaft of the auxiliary transmission 80 is integrally provided at the rear end portion of the main shaft 22 that protrudes rearward from the partition wall portion 12 b of the main case 12.

  The auxiliary transmission 80 holds the sun gear 81, a plurality of, for example, three pinion gears 82 that mesh with the sun gear 81 so as to be able to revolve, and the plurality of pinion gears 82 so as to be capable of rotating through the bearings 83 a and at equal intervals in the revolving direction. The carrier 83 is configured to include an internal ring gear 84 that meshes with a plurality of pinion gears 82, and a sleeve-type meshing switching mechanism 55.

  The auxiliary transmission 80 is accommodated in an auxiliary transmission case 13 whose front side is closed by a partition wall 12 b of the main case 12 on the rear end side of the main case 12 of the transmission case 10. The sun gear 81, the pinion gear 82, the carrier 83, and the ring gear 84 of the auxiliary transmission 80 are similar to known planetary gear reducers. The carrier 83 is supported integrally with the output shaft 24.

  The auxiliary transmission 80 further has a substantially frustoconical cover 85 that is splined to the ring gear 84, and the ring gear 84 is supported coaxially with the output shaft 24 via the cover 85. A known retarder 100 is mounted on the output shaft 24.

  The mesh switching mechanism 55 includes a hub 55a that is rotatably supported with respect to the output shaft 24 via the bearing 25 together with the one end side cylinder portion on the spline-coupled cover 85 side, an annular groove on the outer peripheral side, and an inner peripheral side. And a sleeve 55b having spline teeth to be splined to the hub 55a, and a detent mechanism for urging the sleeve 55b to a neutral position. This engagement switching mechanism 55 has a friction taper surface for synchronizer ring or rotation synchronization, as in the known synchronization engagement mechanism.

  On both sides in the axial direction of the hub 55a, a fixed-side spline 13a that is integrally supported by the auxiliary transmission case 13 and an output-side spline 24a that is coupled to the output shaft 24 by spline coupling or the like in the rotational direction are disposed. ing.

  The sleeve 55b is moved in the axial direction by a shift fork 86 for auxiliary transmission that engages with an annular groove on the outer peripheral side, and meshes with the switching position on the low speed range side that meshes with the fixed side spline 13a and the output side spline 24a. It is designed to move alternatively to the switching position on the high speed range side.

  The shift fork 86 for auxiliary transmission constitutes a part of a known pneumatic operation mechanism 90 for auxiliary transmission, and an operation rod 93 is formed by a piston 92 in a cylinder 91 supported by the auxiliary transmission case 13. The shift fork 86 is operated to move via

  When the sleeve 55b meshes with the fixed-side spline 13a and the ring gear 84 is coupled to the auxiliary transmission case 13 in the rotation direction integrally, the auxiliary transmission 80 outputs the rotational power output from the rear end side of the main shaft 22. Can be output at a relatively low speed and with a large torque.

  Further, when the sleeve 55b meshes with the output-side spline 24a and the ring gear 84 is integrally coupled to the carrier 83 and the output shaft 24 in the rotational direction, the auxiliary transmission 80 is output from the rear end side of the main shaft 22. Rotational power with a small torque can be output at a relatively high speed without decelerating the rotational power.

  On the other hand, on the rear side of the main case 12 of the transmission case 10, a pneumatic counterbrake mechanism 70 capable of outputting a braking force to the countershaft 23 so as to reduce, that is, decelerate the rotational speed of the countershaft 23 is an auxiliary speed change. It is supported by the machine case 13 and provided. Here, the counter brake mechanism 70 uses a pneumatic pressure, that is, a pressure of compressed air, but may be a fluid pressure actuated brake that operates by the pressure of another fluid.

  The sleeves 51b, 52b, and 53b of the mesh switching mechanisms 51, 52, and 53 are moved and operated by the shift forks 61, 62, and 63, and the rotational power input from the input shaft 21 is shifted from the parallel shaft gear transmission 20 to be auxiliary shifted. When output to the machine 80 side, the counter brake mechanism 70 can brake and adjust the rotational speed [rpm] of the counter shaft 23.

  Specifically, at the time of shifting in the upshift direction, for example, upshifting from the 2nd speed to the 3rd speed, the sleeve 52b of the mesh switching mechanism 52 moves in the axial direction toward the main gear 33, so that the 3rd speed main gear 33 becomes the main gear. When coupled to the shaft 22 in the rotational direction, the counter brake mechanism 70 operates.

  More specifically, if the clutch device 3 cuts the power transmission path for shifting and the vehicle speed is changed from the second speed to the third speed while the vehicle speed is substantially constant, the parallel shaft gear transmission 20 When the output rotational speed [rpm] is substantially constant, the transmission gear ratio (input rotational speed / output rotational speed) decreases, and the engine rotational speed decreases so as to approach the rotational speed after shifting. On the other hand, when the sleeve 52b of the mesh switching mechanism 52 is disconnected from the second-speed main gear 32 and returns to the neutral position, the rotational speed [rpm] of the countershaft 23 also decreases due to oil viscosity or the like, but the sleeve 52b of the mesh switching mechanism 52 It takes time to naturally decelerate to the extent that it can be meshed with the third-speed main gear 33. At such time, the counter brake mechanism 70 is operated.

  Further, in the present embodiment, the shift control for controlling the operation input to the shift / select mechanism 60 according to the operation input from the shift lever as a shift request in the upshift direction or based on the vehicle speed, the accelerator position, and the like. In response to a shift request in the upshift direction from the ECU, the electromagnetic switching valve V and the above-described actuators for shift operation are operated.

  On the other hand, the engine control ECU changes the engine speed in response to an operation input that is a shift request in the downshift direction from the shift lever, or in response to a shift request in the downshift direction from the aforementioned shift control ECU. Fuel injection control or the like is executed so as to increase.

  The counter brake mechanism 70 decelerates the rotational speed of the counter shaft 23 according to the operation of the electromagnetic switching valve V described above, for example, when an upshift is requested from the second speed to the third speed. Then, for example, the rotational speed of the counter shaft 23 is decreased so that the spline teeth of the sleeve 52b and the spline 33a of the main gear 33 corresponding to the spline teeth are controlled to a rotational speed difference within a predetermined value.

  Here, the rotational speed difference within a predetermined value is set within a range in which the above-mentioned chamfer portions come into contact with each other by the axial movement of the sleeve 52b and can smoothly shift to a state in which synchronous meshing can be started. Has been.

  At the start of this rotation control, the sleeve 52b of the meshing switching mechanism 52, which has connected the second-speed main gear 32 to the main shaft 22 before shifting, returns to the neutral position, and all main gears including the second-speed main gear 32 are included. 31 to 34 have shifted to a state in which they can idle with respect to the main shaft 22.

  Incidentally, the counter brake mechanism 70 is arranged on the output end side of the main shaft 22 with respect to the counter shaft 23 and the main case 12 of the transmission case 10.

  Specifically, the counter brake mechanism 70 is detachably supported on the outside of the transmission case 10 by being bolted to the brake case 71 integrally supported on the rear end side of the transmission case 10 and the brake case 71. Brake cover 72 is provided.

  In other words, the vehicular transmission of the present embodiment includes an auxiliary transmission 80 that further shifts the rotational power of the parallel shaft gear transmission 20 output from the rear end side of the main shaft 22 and the rear of the transmission case 10. An auxiliary transmission case 13 that houses the auxiliary transmission 80 at the end portion. A brake case 71 of the counter brake mechanism 70 is integrally supported by the auxiliary transmission case 13.

  More specifically, the counter brake mechanism 70 includes a plurality of fixed-side outer disks 73 (fixed-side friction plates) having external splines, and a brake hub 74 that is integrally connected to the counter shaft 23 in the rotational direction. And a plurality of movable inner disks 75 (movable friction plates) on the outer disk 73, which are internally coupled to the brake hub 74 in the rotational direction and are arranged to face the outer disk 73 in a frictional manner. doing.

  Further, the counter brake mechanism 70 receives the pressure of the compressed air on the back side, and can apply pressure to the outer piston 73 and the inner disc 75 on the front side, and the pressure thrust from the brake piston 76. It has a stopper ring 77a and a plurality of receiving plates 77b that press the outer disk 73 and the inner disk 75 with their respective annular friction surfaces while carrying them.

  Between the brake piston 76 and the brake cover 72, a pressurized fluid chamber 78 is defined in which compressed air is supplied or discharged to the outside. The pressurized fluid chamber 78 is formed in the brake cover 72. The compressed air from the pressure accumulation tank P can be introduced through the fluid pressure supply port 72a. Further, in the middle of the air pipe L connecting the fluid pressure supply port 72a to the pressure accumulation tank P, for example, an electromagnetic switching valve V for controlling supply / discharge (supply and discharge) of compressed air to the pressurized fluid chamber 78. Is provided.

  The pressure accumulation tank P is maintained in a pressure accumulation state at a predetermined pressure or higher by being constantly supplied with compressed air during operation of the vehicle by an air compressor (not shown).

  As shown in FIG. 2, the counter brake mechanism 70 also has a round bar-shaped brake shaft 79 that is integrally connected to the counter shaft 23 in the rotational direction by spline coupling or key coupling. The front end 79 a of the brake shaft 79 is made of, for example, the same material as the counter shaft 23 and has a smaller diameter than the counter shaft 23. The rear end 79 b of the brake shaft 79 has a larger diameter than the front end 79 a and is integrally coupled to the brake hub 74 and is rotatably supported by the auxiliary transmission case 13 via the bearing 29. Thus, the brake hub 74 is disposed coaxially and rotatably with respect to the brake case 71, and the plurality of inner disks 75 can be attached / detached from the outside of the auxiliary transmission case 13 by attaching / detaching the brake cover 72. Yes.

  The auxiliary transmission case 13 has a smaller diameter on the rear end side that rotatably supports the output shaft 24 via the bearing 19 with respect to the front end side fastened to the rear end portion of the main case 12. In addition, on the front end side of the auxiliary transmission case 13, the above-described meshing switching mechanism 55 and the like for switching the auxiliary transmission 80 between high and low are accommodated.

  The brake case 71 is a bottomed cylinder that is integrally formed on the outside of the peripheral wall portion 13f constituting the front end portion of the auxiliary transmission case 13, for example, on the lower side on the rear side, and opens in the axial direction opposite to the auxiliary transmission case 13. It is formed in a shape. That is, the brake case 71 has a central axis parallel to the rotation central axes of the main shaft 22 and the output shaft 24 and has a concave shape that opens to the rear side of the vehicle, which is the rear end side of the transmission case 10.

  As shown in FIGS. 2 and 3, the brake cover 72 has a lid-like portion 72 a that closes the opening of the brake case 71 on the vehicle direction side, and the opening of the brake case 71 that forms a part of the auxiliary transmission case 13. A plurality of fastening and fixing portions 72f projecting in the radial direction while being equally spaced in the circumferential direction on the periphery. The brake cover 72 is fastened to the rear end portion of the brake case 71 by a plurality of fastening bolts 72b in the plurality of fastening fixing portions 72f. Between the brake case 71 and the brake cover 72, a gasket 72g and a seal ring 72s are interposed.

  The brake cover 72 further has a cylindrical wall portion 72c that is fitted so as to enter the inside of the brake case 71 from the lid-like portion 72a, and an outer disk 73 is provided on the inner peripheral side of the cylindrical wall portion 72c. An internal spline 72t to be splined is formed.

  These splines 72t are formed on the radially outer side than the cylindrical inner peripheral surface 72i on the inner back side of the cylindrical wall portion 72c of the brake cover 72. Therefore, after storing the brake piston 76 inside the cylindrical wall portion 72c of the brake cover 72, the outer disk 73 and the inner disk 75 are sequentially stored alternately while the outer disk 73 is spline engaged with the spline 72t. Furthermore, a plurality of receiving plates 77b can be accommodated, and the stopper ring 77a having a snap ring shape can be locked to the inner peripheral portion on the inlet side of the cylindrical wall portion 72c.

  That is, the brake piston 76, the outer disk 73, the inner disk 75, the plurality of receiving plates 77b, the stopper ring 77a, and the brake cover 72 that can be attached to and detached from the brake case 71 are sequentially housed in the brake cover 72 from the inner back side. As a whole, a multi-plate brake unit 72U that can be attached to and detached from the brake shaft 79 that is held on the same axis as the counter shaft 23 by the auxiliary transmission case 13 and the bearing 29 is configured.

  Further, in this brake unit 72U, the brake cover 72 and the brake piston 76 can define a pressurized fluid chamber 78 into which a predetermined amount of compressed air can be introduced through the fluid pressure supply port 72a even in the state of being closest to each other. It has an uneven shape in the axial direction.

  At the rear end portion of the brake hub 74, there is a contact member 74a that contacts the center of the front surface of the brake piston 76, and the brake piston 76 is reduced in the direction of reducing the volume of the pressurized fluid chamber 78 via the contact member 74a. A return spring 74b and a collar 74c that are constantly urged are provided.

  The contact member 74a is fitted in a recess 74h that opens to the rear end side of the brake hub 74 so as to be slidable in the axial direction, and on the inner bottom side of the recess 74h, on the outer peripheral surface side of the brake hub 74 or the brake shaft 79. The communicating air hole 74d is formed as shown in FIG. 2 or FIG.

  The front end 79a of the brake shaft 79 also has an air hole 79d that extends from the center to the outer peripheral surface side and communicates the closed space between the rear end portion of the counter shaft 23 and the brake shaft 79 to the outer peripheral surface side of the brake shaft 79. Is formed.

  The brake shaft 79 is less rigid than the countershaft 23, and the vicinity of the portion where the air hole 79d opens on the outer peripheral surface has lower torsional rigidity than other portions that rotate integrally on the same axis. Yes.

  When the braking torque for the countershaft 23 exceeds a preset upper limit value due to the low torsional rigidity part or the part where the cross-sectional area is reduced so as to further reduce the torsional rigidity. A blocking structure 79c (see FIG. 4) having a function of blocking the connection between the counter brake mechanism 70 and the counter shaft 23 is provided.

  Here, the breaking structure 79c is a so-called mechanical fuse, but is constituted by a torque limiter, a clutch or other mechanical connection / breaking means or connection / disconnection switching means that operates when the braking torque exceeds an upper limit value. May be.

  Here, the brake cover 72 is bolted to a brake case 71 integral with the auxiliary transmission case 13, but the outer periphery of the brake cover 72 is screwed to the female thread portion on the opening end side of the brake case 71. You may do it. Of course, any other fixing means can be used, and a fastening form that can be removed only with a special tool can be used.

  Next, the operation will be described.

  In the present embodiment configured as described above, the parallel shaft gear transmission 20 is provided with a plurality of sleeve-type meshing switching mechanisms 51, 52, 53, and any one of the plurality of main gears 31 to 34 can be connected to the main gear. The shaft 22 is selectively coupled to the rotation direction integrally, or the input shaft 21 is selectively coupled to the splitter high gear 35 or the splitter low gear 33, so that the power transmission path is switched so as to be capable of multi-stage shifting. Furthermore, the auxiliary transmission 80 is switched between two levels, high and low, so that the gears are shifted to more stages.

  In such a shift, an upshift direction shift request from the shift control ECU is generated in response to an operation input that is a shift request in the upshift direction from the shift lever, or based on the vehicle speed, the accelerator position, and the like. Thus, the electromagnetic switching valve V for controlling the operation input to the shift / select mechanism 60 and the above-described actuators for shifting operation are operated. Then, the counter brake mechanism 70 operates.

  Now, for example, shifting in the upshift direction, for example, upshifting from the 2nd speed to the 3rd speed is required, and the sleeve 52b of the mesh switching mechanism 52 moves in the axial direction toward the main gear 33, so that the 3rd speed main gear 33 is moved. Assuming that the main shaft 22 is integrally coupled in the rotational direction, the counter brake mechanism 70 is operated at this time.

  Specifically, when the power transmission path is cut by the clutch device 3 for shifting and the vehicle speed is changed from the second speed to the third speed while the vehicle speed is substantially constant, the output of the parallel shaft gear transmission 20 is output. The transmission gear ratio decreases with the rotation speed being substantially constant, and the engine rotation speed decreases so as to approach the rotation speed after the shift. Further, when the sleeve 52b of the mesh switching mechanism 52 is disconnected from the second-speed main gear 32 and returns to the neutral position, all the main gears 31 to 34 are idled with respect to the main shaft 22, and the countershaft 23 of the countershaft 23 is caused by oil viscosity or the like. The rotational speed also decreases.

  At this time, the counter brake mechanism 70 is operated from the braking start timing t1 to the braking end timing t2 shown in FIG. 5, and the rotation speed of the counter shaft 23 is changed from the rotation speed at the second speed before the shift to the rotation at the third speed after the shift. The rotational speed is reduced to a rotational speed close to the number, for example, a rotational speed that is larger by a predetermined ratio than the rotational speed at the third speed.

  Therefore, the spline teeth of the sleeve 52b and the corresponding spline 33a of the main gear 33 can be controlled to a rotational speed difference within a predetermined value in a time sufficiently shorter than the rotational speed of the counter shaft 23 naturally decelerates, and the mesh switching is performed. The sleeve 52b of the mechanism 52 can be quickly meshed with the third-speed main gear 32.

  In the vehicle transmission device 2 of the present embodiment as described above, since the meshing switching mechanisms 51 and 52 are not provided with the synchronizer ring for synchronous meshing, the vehicle transmission device 2 is relatively large as compared with the conventional general vehicle transmission device. A large number of, for example, six annular precision parts can be reduced in diameter. Therefore, it is possible to reduce the cost by simplifying the structure of the apparatus, and it is possible to make the apparatus compact.

  Further, in the mesh switching mechanisms 51 and 52, it is not necessary to provide a friction taper surface between the sleeve and the main gear for rotation synchronization. Therefore, the operation force applied to each mesh switching mechanism 51 and 52 by the shift / select mechanism 60 is applied. Thus, the pneumatic power shift mechanism can be miniaturized, the booster for boosting can be omitted, or the electric actuator such as a motor can be miniaturized. Further, since it is not necessary to synchronize the rotation with the friction surface in the synchronous meshing mechanism, the shift speed due to the movement of the sleeves 51b and 52b can be increased, and the shift time can be shortened.

  Furthermore, in the present embodiment, maintenance work from the outside on the rear end side of the transmission case 10 with respect to the counter brake mechanism 70 becomes possible.

  That is, the brake piston 76, the outer disk 73, the inner disk 75, and the like can be taken out from the brake case 71 simply by removing the brake cover 72 that is sufficiently small in diameter and light with respect to the transmission case 10 from the brake case 71 side. Further, when the brake shaft 79 is splined to the counter shaft 23, the brake hub 74 and the brake shaft 79 can also be removed outward.

  Therefore, when maintenance work for the counter brake mechanism 70 is necessary, another large-scale work for releasing the fastening of the large-diameter portion of the transmission case 10 or removing the vehicle transmission device 2 from the vehicle may be required. Absent. The work is required not only during the maintenance work but also during the initial assembly adjustment of the vehicle transmission device 2.

  In the present embodiment, the counter brake mechanism 70 is detachably supported on the outside of the transmission case 10 with respect to the brake case 71 integrated on the rear end side of the transmission case 10. Therefore, a work space for removing the brake cover 72 from the brake case 71 on the rear side or the lower side of the transmission case 10 can be easily secured, and the workability of the maintenance work itself of the counter brake mechanism 70 is improved.

  In particular, in the present embodiment, the multi-plate type brake unit 72U in which the brake piston 76, the outer disk 73, the inner disk 75, the plurality of receiving plates 77b and the like are housed in the brake cover 72 is provided in the auxiliary transmission case 13 when the vehicle is stopped. The brake cover 72 and the brake shaft 72 can be integrally attached to and detached from the brake shaft 79 held on the same axis as the counter shaft 23 by the bearing 29. Therefore, when the plurality of fastening bolts 72b are removed and the brake cover 72 is removed from the brake case 71, the multi-plate brake unit 72U can be separated from the brake hub 74 of the brake shaft 79 that is stationary at a fixed position.

  Further, when the brake cover 72 is remounted on the brake case 71, the brake unit 72U after maintenance work can be easily splined to the brake hub 74 simply by making the angular position in the rotational direction of the brake cover 72 the same as when the brake cover 72 is removed. Can be combined.

  Further, the brake shaft 79 and the bearing 29 itself can be easily removed to the outside of the transmission case 10 simply by pulling outward or removing the retaining ring 29a. It can be done easily with the procedure.

  As a result, the structure of the vehicle transmission device 2 can be made simple and smooth, and the work required for maintenance of the counter brake mechanism 70 can be greatly facilitated.

  In addition, in this embodiment, the auxiliary transmission 80 that further shifts the rotational power after the main shift output from the rear end side of the main shaft 22 and the auxiliary transmission 80 are accommodated on the rear end side of the transmission case 10. The brake case 71 of the counter brake mechanism 70 is integrally supported by the auxiliary transmission case 13. Therefore, the number of parts of the counter brake mechanism 70 can be suppressed.

  Further, the counter brake mechanism 70 can output a braking force to the counter shaft when supplying compressed air pressure, and thus is suitable for a vehicle that frequently uses a pneumatic actuator utilizing the compressed air pressure.

  In addition, in the present embodiment, the brake shaft 79 of the counter brake mechanism 70 is provided with a blocking structure portion 79c that can mechanically block the braking force against the counter shaft 23. Therefore, it is possible to prevent an excessive braking torque or rotational resistance torque from acting on the countershaft 23 when an abnormality occurs due to a failure of the counterbrake mechanism 70 or the like, and the failsafe function can be enhanced.

  In the above-described embodiment, the auxiliary transmission 80 and the auxiliary transmission case 13 are disposed behind the main case 12 of the transmission case 10, but there is no auxiliary transmission such as the auxiliary transmission 80. Alternatively, it may be arranged in front of the transmission case. Further, the counter brake mechanism 70 is a multi-plate brake mechanism, but may be another type of brake having good response, and may be an electromagnetic type instead of a pneumatic type. Further, the brake case 71 of the counter brake mechanism 70 is formed integrally with the auxiliary transmission case 13, but the cup-shaped brake case 71 itself is formed in a concave portion that is formed on the auxiliary transmission case 13 side and opens rearward. It may be fitted or screwed together. Further, although the shift in the upshift direction has been described as the shift from the second speed to the third speed in the parallel shaft gear transmission 20, the present invention can also be applied at the time of shifting at an arbitrary shift stage or at the time of interlaced shifting. . In the above-described embodiment, the rear case side vehicle rear side of the transmission case has been described. However, the rear end side of the transmission case referred to in the present invention is the speed change output shaft side, and is not necessarily the rear side of the vehicle. . Therefore, it is also conceivable to apply the vehicle transmission of the present invention to a vehicle transmission that changes the rotational power from a so-called horizontal engine.

  As described above, the vehicle transmission of the present invention has a simple structure and enables smooth gear shifting, and also allows maintenance work from the outside of the rear end side of the transmission case to the counter brake mechanism. The maintenance work of the counter brake mechanism can be greatly facilitated by eliminating the need for a large-scale separate operation for releasing the fastening of the large-diameter portion of the transmission case or removing the vehicle transmission device from the vehicle. The present invention is useful for general multi-stage vehicle transmissions equipped with a countershaft.

DESCRIPTION OF SYMBOLS 1 Engine 2 Vehicle transmission device 3 Clutch device 6 Oil pump 10 Transmission case 11 Clutch case 12 Main case 13 Auxiliary transmission case 13f Peripheral wall portion 20 Parallel shaft gear transmission 21 Input shaft 22 Main shaft 23 Counter shaft 24 Output shaft 31, 32, 34 Main gear 31a, 32a, 33a, 33b, 34a Spline 33 Main gear (splitter low gear)
35 Splitter high gear 36, 37, 38, 39 Transmission gear pair 40H Splitter high gear pair 40L Splitter low gear pair 41, 42, 43, 44, 45 Counter gear 51, 52, 53 Meshing switching mechanism 51a, 52a, 53a Hub 51b, 52b, 53b Sleeve 60 Shift / select mechanism 61, 62, 63 Shift fork 70 Counter brake mechanism 71 Brake case 72 Brake cover 72a Lid part 72p Fluid pressure supply port 72U Brake unit 73 Outer disk (Friction plate on the fixed side)
74 Brake hub 75 Inner disc (movable friction plate)
76 Brake Piston 78 Pressurized Fluid Chamber 79 Brake Shaft 79a Front End 79b Rear End 79c Blocking Structure 80 Auxiliary Transmission L Air Piping P Accumulation Tank V Electromagnetic Switching Valve

Claims (4)

A transmission case, a main shaft and a counter shaft that are rotatably supported by the transmission case in parallel with each other, a plurality of main gears that are supported by the main shaft so as to be idle, and the counter shaft that is always meshed with the main gear. A plurality of speed change gear pairs including a plurality of counter gears supported by a shaft, a sleeve movable in an axial direction so as to be integrally engaged with and disengaged from a corresponding main gear among the main gears in a rotational direction, and the counter shaft A counter brake mechanism capable of outputting braking force against
When the sleeve is integrally engaged with the corresponding main gear in the rotational direction, the rotational power input from the front end side of the transmission case is shifted and the rotational power after the shift is output from the rear end side of the transmission case. A vehicle transmission,
The counter brake mechanism is disposed on the rear end side of the transmission case;
The counter brake mechanism has a front end portion integrally connected to the counter shaft in a rotation direction and a rear end portion formed with a spline, and is supported rotatably on the transmission case, and the brake shaft A vehicular transmission comprising: a brake unit that can be splined to a rear end portion.   The vehicle transmission according to claim 1, wherein the brake shaft is detachably connected to the countershaft. The counter brake mechanism has a multi-plate brake unit that can be attached to and detached from the brake shaft;
The vehicular transmission according to claim 1 or 2, wherein a brake hub that is splined to the brake unit is connected to a rear end portion of the brake shaft. The brake unit includes a fixed side and a movable side friction plate, a brake piston that presses both friction plates, and a brake cover.
The transmission for a vehicle according to claim 3, wherein the brake cover accommodates the fixed and movable friction plates and the brake piston.

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