Abstract:
An automatic transmission of a trans-axle type in which an input shaft is disposed above a differential across an axle of a vehicle. A case for the transmission is divided into a differential case for mounting a differential and a transmission case for an automatic transmission device. A bearing plate is disposed between the differential case and the transmission case. A drive pinion formed on an end of a drive pinion shaft is engaged with a ring gear of the differential. The drive pinion shaft is rotatably mounted in the bearing plate by a bearing, and an oil pump is provided in the bearing plate around the input shaft.

Description:
RELATED APPLICATION 
     This a continuation-in-part of my co-pending patent application Ser. No. 052,631, now abandoned, filed May 20, 1987. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to an automatic transmission for a motor vehicle, and more particularly to a trans-axle type automatic transmission, an input shaft of which extends across an axle of the vehicle. 
     An automatic transmission in which an oil pump is disposed in a differential chamber is known. For example, French Patent 1,526,585 discloses an automatic transmission having an oil pump in a differential chamber. However, the differential chamber is expanded in the axial direction for the oil pump. Accordingly, the axial length of the transmission is increased. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to provide a trans-axle type automatic transmission the axial length of which may be reduced. 
     Another object of the present invention is to provide an automatic transmission which is improved in efficiency of assembling and adjustment of bearings. 
     Accordingly to the present invention, there is provided an automatic transmission having an automatic transmission device, an input shaft disposed above a differential, a drive pinion shaft disposed in parallel with the input shaft, and a drive pinion formed on an end of the drive pinion shaft being engaged with a ring gear of the differential. 
     The transmission comprises a differential case for mounting the differential, a transmission case for the automatic transmission device, a bearing plate disposed between the differential case and the transmission case, the drive pinion shaft being rotatably mounted in the bearing plate by a bearing at an end portion adjacent the drive pinion, and an oil pump provided in a recess in the bearing plate around the input shaft. 
     The other objects and features of this invention will become understood from the following description with reference to the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF DRAWINGS 
     FIGS. 1a and 1b show an automatic transmission according to the present invention in section; 
     FIG. 2 is a sectional view taken along a line II--II of FIG. 1a; and 
     FIG. 3 is an enlarged view showing a part of FIG. 1a. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring to FIGS. 1 and 2, the automatic transmission has a transmission case 1, a pair of differential covers 2 for forming a differential case secured to an engine block (not shown), and an extension case 3. A bearing plate 4 is disposed between the transmission case 1 and the differential covers 2. A crankshaft 5 of an engine E is connected to an impeller 6 of a torque converter 7. A turbine 8 of the torque converter is connected to an input shaft 10 which is operatively connected to an automatic transmission device 11 in the transmission case 1. The automatic transmission device 11 has a reverse clutch 14, forward clutch 15, low and reverse brake 16, one-way clutch 17, reverse sun gear 18, forward sun gear 19, and ring gear 20. The function and operation of the transmission is well known and is the same as that of U.S. Pat. No. 4,480,505, incorporated by reference herein. The ring gear 20 is connected to a reduction drive gear 21 in the extension case 3. The reduction drive gear 21 is engaged with a reduction driven gear 22 which is secured to a rear portion of a drive pinion shaft 31. The drive pinion shaft 31 is disposed in substantially parallel with the input shaft 10. Opposite bosses 27, 28 of the driven gear 22 are rotatably supported by bearings 29, 30 in the transmission case 1 and extension case 3. A drive pinion 33 at the front end of the drive pinion shaft 31 is engaged with a ring gear 34 of a front differential 35. 
     In accordance with the present invention, a front portion of the drive pinion shaft 31 is rotatably supported in the bearing plate 4, and further an oil pump 36 for the automatic transmission device 11 is provided in the bearing plate 4, as described hereinafter in detail. 
     As shown in FIG. 3, a front end portion of the drive pinion shaft 31 is supported by a double taper roller bearing 40. The bearing 40 comprises a front inner race 41 and a rear inner race 42 which are secured to the shaft 31, taper rollers 43, 44, and an outer race 45 engaged with a hole 4a formed in the bearing plate 4. The outer race 45 has a flange 45a at the front side thereof. The inner races 41, 42 are held between a boss 33a of the pinion 33 and a sleeve 46 which is axially secured to the shaft 31 by a nut 47 interposing a washer 48. The flange 45a of outer race 45 is secured to the bearing plate 4 by bolts 50 interposing a shim 51. The roller bearing 40 is sealed by an annular oil seal 52 provided between the sleeve 46 and a retainer 53 secured to the bearing plate 4 by bolts 54. 
     The oil seal 52 is provided between the adjusting means (comprising the sleeve 46, which is axially adjustably disposed on the shaft 31, and the lock nut 47) and the retainer 53, thereby sealing a partitioning means (comprising the bearing 40, the retainer 53, and the sleeve 46) to hydraulically separate the differential chamber (defined by the differential case) and the transmission chamber (defined by the transmission case 1) from each other. 
     Different types of lubricating oil, each different type being specially suited and proper for lubricating the respective devices and gears in the differential chamber, on the one hand, and the transmission chamber, on the other hand, are provided and used for lubrication in these two respective chambers. In other words, two different oils suitable for these separate parts of the system can be used in these two chambers, since the different oils do not mix with each other by the seal 52 and the partitioning means which seals and partitions the differential and transmission chambers on both sides of the hole 4a in the bearing plate 4. 
     The retainer 53 has an enlarged diameter sleeve portion, which engages around a portion of the outer race 45 which extends beyond the bearing plate 4 toward the transmission chamber, abutting the bearing plate 4 with an annular gasket or seal interpositioned against the outer race 45, the bearing plate 4 and the enlarged diameter sleeve portion of the retainer 53. A reduced diameter sleeve portion of the retainer 53 engages around the oil seal 52, which seal 52 comprises oppositely inverted annular seals aligned adjacent the taper rollers 44. 
     The oil pump 36 is a type of a gear pump provided in a recess 55 formed in the bearing plate 4 at the transmission side. As shown in FIG. 1a, the oil pump 36 is provided around the input shaft 10 and comprises an eccentric outer gear 56 and an inner drive gear 57 coaxial with the input shaft, and a pump cover 61 secured to the bearing plate 4 to hold the gears. The drive gear 57 is connected to the impeller 6 of the torque converter 7 through a sleeve 60. The pump cover 61 has a sleeve 58 disposed between the sleeve 60 and the input shaft 10. 
     The oil pump 36 supplies hydraulic oil to the automatic transmission device 11 and to the lockup clutch (at the left of the turbine 8 in FIG. 1a) of the torque converter 7 for their operation. 
     The automatic transmission is assembled in the following manner. The transmission case components and extension case components are preliminarily assembled. The drive pinion shaft 31 is supported by the double taper roller bearing in the bearing plate 4. At that time, the pre-load of the bearing 40 is adjusted by the lock nut 47 (the lock nut 47 being adjustably threaded on cooperating threads on the shaft 31) and by the degree of interference fit of inner races 41, 42 and shaft 31. The position of the drive pinion 33 for the ring gear 34 is adjusted by the number or thickness of the shim or shims 51 to a proper value. The oil pump 36 is assembled in the recess 55 and cover 61 is attached to the bearing plate 4 after adjustment of oil pump members. The bearing plate assembly is attached to the transmission case assembly. The driven gear 22 is mounted on the pinion shaft 31 and supported by bearing 29, and secured by nut 62. The extension case assembly is connected to the transmission assembly supporting the shaft 31 by bearing 30. Therefore, torque converter 7 is operatively connected to the oil pump 36 and automatic transmission device 11. The differential 35 is attached to one of the covers 2 and both covers are secured to the bearing plate, so that the automatic transmission is assembled. 
     In accordance with the present invention, the oil pump is disposed in the bearing plate for the drive pinion shaft. Accordingly, the oil pump can be mounted in the transmission without providing a special space. Thus, the axial length and the weight of the automatic transmission can be reduced. Since the transmission case assembly and the torque converter case assembly are separately assembled, productivity of the transmission can be improved. The adjustment of the bearing of the drive pinion can be easily performed without obstacles. 
     While the presently preferred embodiment of the present invention has been shown and described, it is to be understood that this disclosure is for the purpose of illustration and that various changes and modifications may be made without departing from the spirit and scope of the invention as set forth in the appended claims.