DE3524081A1 - Torque converter with an infinitely variable belt or chain drive - Google Patents

Abstract

In a torque converter with an infinitely variable belt or chain drive, especially a V-belt drive, which has a drive pulley and a driven pulley, which are coupled to one another by way of a belt or chain, the drive pulley being seated on a drive shaft which can be coupled to a drive assembly and the driven pulley being seated on a driven pulley shaft, which is coupled to a driven shaft, a gear transmission and a variable-speed transmission are also provided, the gear transmission being coupled on the drive side to the drive shaft and the variable-speed transmission serving both for coupling the driven pulley shaft to the driven shaft and for coupling the driven pulley shaft to the output side of the gear transmission. A differential gear is preferably provided as variable-speed transmission.

Description

The invention relates to a torque converter with a infinitely variable traction mechanism transmission, especially one V-belt transmission, which has a drive pulley and an Ab has drive pulley which ge with each other via a traction means are coupled, with the drive pulley on one to one drive unit can be coupled to the drive shaft and the Ab drive pulley is seated on a driven pulley shaft, which an output shaft is coupled.

In known torque converters with a continuously variable control traction mechanism is dependent on the control range transmitted power via the traction mechanism transmission and takes away increasing performance. Especially when transferring height However, their performance is the gentle starting or braking of the Gearbox desired or even, e.g. B. for the sake of acceleration of larger masses is absolutely necessary. Because the rule  well-known traction mechanism is not large enough gearboxes not used in many areas and this with an adjustable drive, such as. B. an electromo gate, coupled, which is a rule of speed in the range of 0 - 100% allowed, although the use of an adjustable traction means drive in conjunction with a non-controllable drive would be more economical.

The invention is based, with a Drehmo the task ment converter with a continuously adjustable traction mechanism the controllability, especially around the zero range, to improve ser.

According to the invention, this object has been achieved by that the torque converter in addition a gear and a Superposition gear has that the gear drive is coupled on the side to the drive shaft and that the overload gearing both for coupling the driven pulley shaft with the output shaft, as well as for coupling the output disc benwelle provided with the output side of the gear train is.

A superposition takes place through the superposition gear the output speed of the traction mechanism and the wheel driven instead. This allows the torque to be regulated ment converter, depending on the existing in the gear train Gear ratio between drive and output, in particular improve around the zero range.  

Preferably, the traction mechanism and the wheel are drives designed so that they were opposite directions of rotation distant, which partially cancel each other out in the superposition gear. From depending on the gear ratio selected in the gear train can then shift the control range of the torque converter ben that it is in a speed range in which the Output shaft speed can be reduced to zero can. The transmission ratio can also be chosen in this way be that within the control range a change in Direction of rotation of the output shaft can be effected, the Drive unit continues to run in constant direction of rotation. With such a design of the torque according to the invention converter can also be used when using an internal combustion engine Drive unit changed the direction of rotation of the output shaft without the need for a reversing gear and a clutch are. When using an electric motor as a drive unit occur because the electric motor itself its direction of rotation does not have to change, no harmful surges or voltage Breaks in and the electric motor becomes less thermally burdens.

Through the superposition gear, which is the traction mechanism and the gear train with each other and with the output shaft couples, there is a power split in the torque converter instead of.

With increasing power transmission, it is advantageously possible  Lich, proportionately less and less power over the traction means drives to transmit. The traction mechanism of the invention ß torque converter can be compared to known Zugmit smaller with the same power to be transmitted can be designed, or it can be designed with the same size Traction mechanism transmissions transmit a higher output.

Especially when the gear train is concerned a gearbox is the overall efficiency of the Torque converter according to the invention larger than that of a ver comparable known traction mechanism because a large proportion the power is transmitted from the gear transmission, which on due to the meshing of the gears a lot higher ren efficiency, as a controllable traction mechanism be, in which the traction device is usually a V-belt on which relatively high friction losses and slippage occur.

The superimposition gearbox replaces a mostly already anyway Such transmission gear, so that in the manufacture of the torque converter according to the invention advantageously none Additional costs for a comparable known transmission would arise hen.

In a preferred embodiment of the invention The torque converter is the transmission gear as the difference tial gear trained, the differential gear Bevel gear differential can be four with each other has intermeshing bevel gears, which are arranged to each other  are that one of the bevel gears each side of a rake teckes forms. Here, one of two is preferably one other opposite bevel gears with the drive pulley of the traction mechanism non-rotatably connected, while the other Bevel gear connected to the output side of the gear train is. The speed of the other two bevel gears results then from a superposition of the output speeds of the train telgetriebes and the gear transmission and is preferably di transmitted directly to the output shaft.

Of particular advantage is the differential gear provided that from two opposite Kegelrä of the four bevel gears, the first bevel gear with the output disc shaft is rotatably connected that the second bevel gear via an output gear shaft with a the output side of the Gear train forming output gear is rotatably connected and that the third bevel gear and the fourth bevel gear are coaxial free to each other on a common connection axis are rotatably arranged. The one with the connection axis other connected bevel gears roll on the first bevel gear and on the second bevel gear and don't just turn around their own axis, which coincides with the connecting axis len, but they also revolve around their common geometry center, with the connection axis around the connection axis center is rotated. The rotation of the verbin tion axis is preferably on the output shaft  wear by the output shaft at a preferred training extension of the torque converter according to the invention at one end fixed to the center of the connecting axis, perpendicular to the ver binding axis standing, connected and the output shaft through the driven wheel shaft designed as a hollow shaft is led.

The gear train preferably consists only of the arranged on the driven gear shaft and a driven gear drive wheel arranged on the drive shaft, which as mitein other meshing gears, preferably spur gears forms and which are a predetermined gear ratio exhibit. Since the driven wheel and the drive wheel two together the output gear shaft has other meshing gears a different direction of rotation than the drive wheel shaft, while the Driven pulley shaft as the traction device normally does not cross the same direction of rotation as the drive shaft sits. This will lift them over the gearbox and that Traction mechanism gearbox transferred directions of rotation in the superposition gear partially on, so that by regulating the Zugmittelge drive and the speeds transmitted by it the rotation number of the output shaft can be regulated. In the area of low Low speeds can advantageously control up to the point be made in which a via the traction mechanism same speed is transmitted as over the wheel drives and the output shaft thus comes to a standstill. By a  Change the gear ratio of the drive wheel and Driven wheel by simply replacing the drive wheel the and the driven gear by gears of other diameters can follow, the control range of the torque converter in advantageously in a range higher or lower Output shaft speed can be shifted.

In another embodiment of the torque according to the invention mentwandlers is the superposition gear as a planetary gear be trained.

In such an embodiment it is provided that the wheels gear from a non-rotatably arranged on the drive shaft Drive wheel and a meshing with this drive wheel an output gear shaft designed as a hollow shaft ten driven gear is that the driven gear face and ver coaxially with an outer ring gear of the planetary gear is bound that the output shaft through the driven gear shaft is passed and point at it to the traction mechanism the end of a planetary gear arranged coaxially to the ring gear ger has that the driven pulley shaft on its the wheels gear end facing a coaxial to the ring gear has ten sun gear and that the sun gear and the ring gear via at least one freely rotatable on the planet carrier Comb the ordered planet gear. The driven gear of the Gear train and the driven pulley of the traction mechanism preferably have an opposite direction of rotation. The  The direction of rotation of the driven pulley is via the driven pulley shaft le transferred directly to the sun gear of the planetary gear, while the ring gear of the planetary gear is preferably direct is placed on the driven wheel and the same direction of rotation as the driven gear has. The sun gear and the ring gear of the planetary gear are arranged so that their Sprockets lie on one level. Between these sprockets at least one of the ring gear and sun gear rolls on a tarpaulin planet gear arranged from, whereby the the Ach se of the planet carrier output shaft forming a speed and receives a sense of rotation resulting from an overlay of the rotation numbers and the direction of rotation of the driven pulley and driven gear result. Due to the gear ratio between Ab drive wheel and drive wheel of the gear train can again Change control range of the torque converter according to the invention be changed, especially when using a pla Netengetriebes as a superposition gear by choosing the ge suitable gear ratio in the gearbox and through Regulating the traction mechanism a reversal of the tarpaulin tenradträger and thus the output shaft possible, while that Drive unit runs continuously in the same direction.

According to a development of the invention, the inventor torque converter according to the invention with a dome with two wheels hard differential gear. Especially because with the inventions torque converter according to the invention regulates the output rotation  number in a wide range and a reversal of movement without Coupling are possible, the torque wall according to the invention Particularly advantageous for use in one with one Internal combustion engine powered motor vehicle suitable because the Gear ratio can be chosen so that the internal combustion engine always works in the optimal operating range. The compensation ge drives advantageously ensures a track-safe drive Impellers, especially when cornering. The end same gear is advantageous in the two driven barrel wheels connecting axis used, for example wise with a propeller shaft with the drive shaft of the torque mentwandlers can be connected, but also the output wave itself can be.

In a particularly advantageous embodiment, this is Differential gear with the superposition gear, or cone Rad-differential gear combined, with the wheels on the output shaft itself are arranged. The expulsion shows same gear four intermeshing differential bevel gears on the inside of the bevel gear of the bevel gear dif ferential transmission formed rectangle are arranged and each of which has a differential bevel gear coaxial with one of the Bevel gears of the bevel gear differential gear is arranged. The individual gears, namely the tension means gears, the gear train, the superposition gear and that Differential gear, and corresponding actuators for  Adjusting the traction mechanism gear essential to the invention Advantageously housed in a common housing from which then only the drive shaft and the Ab protruding drive shaft.

In a further embodiment of the differential gear is before seen that the third differential bevel gear and the fourth off same bevel gear coaxial with the third bevel gear and the fourth bevel gear of the bevel gear differential are freely rotatable on the connecting axis of these bevel gears are stored that the first differential bevel gear, which ko xial to the first bevel gear, rotatably on a with a first impeller detachable output half-wave of the ge shares trained output shaft is arranged that the two te differential bevel gear, which is coaxial with the second bevel gear is arranged on the coupling with a second impeller second output half-wave is arranged and that from the Ab drive half-waves the first output half-wave through the as Hollow shaft-formed driven pulley shaft and the second Output half-shaft formed by the hollow shaft drive wheel shaft is passed. The sense of rotation and the Speed of the driven pulley is on the first bevel gear of the Bevel gear differential gear and the speed and the rotation Direction of the driven gear is on the second bevel gear Bevel gear differential transmission, so that the third and the fourth bevel gear, which coincide with the connecting axis  are connected between the first bevel gear and the roll off the second bevel gear and do it together geometric center that is roughly in the middle of the connection axis, rotate and take the connecting axis with it, which in a plane parallel to the first and second Bevel gear rotates. Because the third differential bevel gear and that fourth differential bevel gear like the third bevel gear and that fourth bevel gear rotates freely on this connecting axis are arranged, they rotate with the connection axis taken along by this, being the first compensation key gelrad and the second differential bevel gear, which would mesh with them set in rotation. The first differential bevel gear and the second differential bevel gear are on the output half-shafts connected to the wheels so that the wheels are also are driven. When driving straight ahead, where the Turning the wheels at the same speed leads to the third compensation bevel gear and the fourth differential bevel gear no rotation by the connection axis, but they are from the verb axis only in a rotation around their common geome tric center, where they the first equalizing key gelrad and take the second differential bevel gear with you doing so with the same speed and the same sense of rotation around their egg turn the opposite axes together with the output half-shafts fall. When cornering, the outer one rolls, the longer one Impeller traversing a curve at a higher speed  from. Therefore, the differential bevel gear, which has an output half shaft is connected to this impeller, for example that second differential bevel gear, driven faster than the other compensation cone connected to the other impeller rad, in this case the first differential bevel gear. This ge is characterized in that the third differential bevel gear and the fourth differential bevel gear now opposed to each other move around the common connection axis, doing the first Retain differential bevel gear while holding the second Advance differential bevel gear faster.

The connecting axis has a floating bearing approximately in the middle, through which the free end of the second output half-wave freely rotatable and perpendicular to the connection axis leads and engages the free end of the second output half shaft in a arranged on the first differential bevel gear Bearing mount rotates freely. The inventory takes place in Principle of a continuation of the first, designed as a hollow shaft Output half-shaft through the first differential bevel gear, in which engages the second output half-wave. This will help with Advantage of a better stiffening in the output half-waves split output shaft achieved.

Embodiments from which further inventive Characteristics result are shown in the drawing. Show it:  

Fig. 1 is a schematic diagram of a gear according to the torque converter with a fiction, Differentialge,

Fig. 2 is a schematic plan of a torque converter according to the Invention with a planetary gear and

Fig. 3 is a schematic plan of a torque converter according to the invention with a differential.

In Fig. 1, an inventive torque transducer is shown, having a traction mechanism 1 and a gear train 2, which are coupled via a hole formed as a bevel gear differential gear 3 superposition gearing on the output side with each other. The traction mechanism transmission 1 has a drive pulley 4 on the drive side, and the wheel transmission 2 has a drive wheel 5 which are seated on a common drive shaft 6 of a drive unit 7 . The drive pulley 4 of the traction mechanism gear 1 is coupled via a traction mechanism 8 to a drive pulley 9 , which is arranged on an output pulley shaft 10 . The drive wheel 5 of the gear train 2 , which is designed as a spur gear, is in operative connection with an output gear 11 , which is also designed as a spur gear and sits on egg ner output gear shaft 12 , which is designed as a hollow shaft. The driven pulley shaft 10 and the driven gear shaft 12 are coupled to one another via a differential gear designed here as a bevel gear differential 3 . The bevel gear differential gear 3 has four intermeshing bevel gears 13, 14, 15, 16 , which are arranged so that a bevel gear forms one side of a right corner. A first bevel gear 13 is connected via the driven pulley shaft 10 to the driven pulley 9 , while a second bevel gear 14 , which lies opposite the first bevel gear 13 coaxially, is connected via the driven gear shaft 12 to the driven gear 11 . The third bevel gear 15 and the fourth bevel gear 16 , which are also coaxially opposite each other, are freely rotatable on a common Verbindungsach se 17 arranged. With the center of the connecting axis 17 , one end of an output shaft 18 is connected, which is perpendicular to the connecting axis 17 and which is guided through the driven wheel shaft 12 designed as a hollow shaft. If the first bevel gear 13 and the second bevel gear 14 are driven in opposite directions to one another via the drive pulley 9 and the driven gear 11 , the third bevel gear 15 and the fourth bevel gear 16 roll between the first bevel gear 13 and the second bevel gear 14 . If the speed of the driven pulley 9 and the driven gear 11 are unequal in size, then when the third bevel gear 15 and the fourth bevel gear 16 roll, their common connecting rod 17 and thus the output shaft 18 are set in rotation. The speed of the output shaft 18 results from the ratio of the speed of the driven pulley 9 and the driven gear 11 to one another, which can be changed by changing the transmission ratio between the driven gear 11 and the drive gear 5 or continuously via the traction mechanism 1 . In particular, a choice of the gear ratio between the driven wheel 11 and the drive wheel 5 can be selected, in which the direction of rotation of the output shaft 18 can be changed by regulating the traction mechanism transmission 1 without the drive shaft 6 having to change its direction of rotation.

Fig. 2 shows an embodiment of a torque converter according to the invention in which, instead of the bevel gear differential 3 shown in FIG. 1, a planetary gear 19 is used as a superposition gear. The same components are identified by the same reference numerals as in FIG. 1.

The planetary gear has an outer ring gear 20 which is connected directly to the driven gear 11 of the gear transmission 2 . Centrally to this ring gear 20 is a sun gear 21 is arranged, which is connected via the driven pulley shaft 10 to the driven disk 9 of the traction mechanism 1 . A planet gear carrier 22 is arranged coaxially with the ring gear 20 and the sun gear 21 , the axis of which is the output shaft 18 and is arranged on the planet gears 23 , via which the sun gear 21 and the ring gear 20 mesh with one another.

The planetary gear 19 in the embodiment shown in Fig. 2 has the same function as the bevel gear DIF differential gear 3 in the embodiment shown in Fig. 1 example, the ring gear 20 the function of the second bevel gear 14 , the sun gear 21 the function of Bevel gear 13 and the planet gears 23 take over the function of the third bevel gear 15 and the fourth bevel gear 16 . Instead of a binding axis Ver 17, the planet wheels 23, since they lie in a plane ver each other via the planet carrier 22 connected.

Fig. 3 shows an embodiment of a torque converter according to the invention, in which the bevel gear differential gear 3 is combined with a differential gear 24 . The same components are identified by the same reference numerals as in FIG. 1.

Within the bevel gear differential gear 3 , the differential gear 24 is arranged, which has four differential bevel gears 25, 26, 27, 28 , the first differential bevel gear 25 the first bevel gear 13 , the second differential bevel gear 26 the second bevel gear 14 , the third differential bevel gear 27 the third Bevel gear 15 and the fourth differential bevel gear 28 are coaxially assigned to the fourth bevel gear 16 . The third equalization bevel gear 27 and the fourth differential bevel gear 28 , like the third bevel gear 15 and the fourth bevel gear 16 , are freely rotatable on the common connecting axis 17 . The first differential bevel gear 25 is connected via a first differential half shaft 29 to a first impeller 30 and the second equalizing gear 26 is connected via a second output half shaft 31 to a second impeller 32 of a split output shaft 18 . For centering, the connecting axis 17 has a floating bearing 33 in the center, in which the second drive half-shaft 31 is supported by its free end, this free end of the second output half-shaft 31 engaging in a bearing receptacle 34 arranged on the first differential bevel gear 25 . The impellers 30, 32 are shown in section in FIG. 3. The driven pulley shaft 10 and the driven gear shaft 12 are formed as hollow shafts, to a Hindurchfüh ren the group consisting of the output half-shafts 29, 31 driven shaft to allow the eighteenth

If the first bevel gear 13 and the second bevel gear 14 are driven in opposite directions via the driven pulley 9 and the driven gear 11 , the third bevel gear 15 and the fourth bevel gear 16 roll between the first bevel gear 13 and the second bevel gear 14 . If the speeds of the first bevel gear 13 and the second bevel gear 14 are not of the same magnitude, the connecting axis 17 is set in rotation when the third bevel gear 15 and the fourth bevel gear 16 roll. Since the third differential bevel gear 27 and the fourth differential bevel gear 28 are also arranged on this connecting axis 17 , who they take with them from the connecting axis 17 during rotation. Since the third pinion gear 27 and the fourth from gleichskegelrad 28 with the first pinion 25 and second pinion 26 mesh, while he ste pinion 25 and the second pinion gear 26 are also rotated, with them the Abtriebshalbwel len 29, 31 and thus also the wheels 31, 32 . In a Gera deausfahrt the wheels 30, 32 rotate at the same speed. When cornering, the two wheels 30, 32 must rotate at different speeds, since they have to cover different distances in the same times. Assuming that the second impeller 32 has to rotate faster than the first impeller 30 , the second differential bevel gear 26 must drive the second impeller 32 via the second output half-shaft 31 faster than the first differential bevel gear 25, the first impeller 30 via the first output half-shaft 29 . This is because the third differential bevel gear 27 and the fourth differential bevel gear 28 rotate in opposite directions to one another around the common connecting axis 17 and thereby hold back the first differential bevel gear 25 and at the same time push the second equalization bevel gear 26 out faster, while doing this in a straight line turn the third differential bevel gear 27 and the fourth differential bevel gear 28 only around the common geometric center, which is approximately in the middle of the connecting axis 17 , but not about the connecting axis 17 .

Claims (13)

1. Torque converter with a continuously variable train medium transmission, in particular a V-belt transmission, which has a drive pulley and a driven pulley, which are coupled to each other via a traction means, the drive pulley being seated on a drive shaft that can be coupled to a drive unit, and the driven pulley is seated on a driven pulley shaft , which is coupled to an output shaft, characterized in that it additionally has a gear train ( 2 ) and a gearbox overlay, that the gearbox ( 2 ) is antriebssei tig coupled to the drive shaft ( 6 ) and that the overlaid gearbox both for coupling the Output disc shaft ( 10 ) with the output shaft ( 18 ), and also for coupling the output disc shaft ( 10 ) with the output side of the gear drive ( 2 ) is provided. 2. Torque converter according to claim 1, characterized net that the superposition gear as a differential gear is trained. 3. Torque converter according to claim 2, characterized in that the differential gear is a bevel gear-Differentialge gear ( 3 ) having four intermeshing bevel gears ( 13-16 ) which are arranged so that one of the bevel gears ( 13 - 16 ) forms the side of a rectangle. 4. Torque converter according to claim 3, characterized in that of two opposite bevel gears ( 13, 14 ) of the four bevel gears ( 13 - 16 ), the first bevel gear ( 13 ) with the driven pulley shaft ( 10 ) is rotatably connected that the second bevel gear (14) forming an output wheel shaft (12) with a the output side of the gear train (2) driven wheel (11) is rotationally fixedly connected, and in that the third bevel gear (15) and the fourth bevel gear (16) coaxially with one another joint on one them connection axis (17 ) are freely rotatable net. 5. Torque converter according to claim 4, characterized in that the output shaft ( 18 ) at one end is fixed to the center of the connecting axis ( 17 ), perpendicular to the Verbindungsach se ( 17 ), and that the output shaft ( 18 ) by the driven wheel shaft ( 12 ) is designed as a hollow shaft. 6. Torque converter according to one of the preceding Ansprü surface, characterized in that the gear train ( 2 ) from the driven gear shaft ( 12 ) arranged driven gear ( 11 ) and one on the drive shaft ( 6 ) arranged drive wheel ( 5 ), which as one with the other Intermeshing gears, preferably as spur gears, are formed which have a predetermined transmission ratio. 7. The device according to claim 1, characterized in that the superposition gear is formed out as a planetary gear ( 19 ). 8. The device according to claim 7, characterized in that the gear train ( 2 ) from a non-rotatably arranged on the drive shaft ( 6 ) drive wheel ( 5 ) and a meshing with this drive wheel ( 5 ) on a trained as a hollow shaft th driven wheel shaft ( 12 ) arranged driven gear ( 11 ) be that the driven gear ( 11 ) on the end face and coaxially with an outer ring gear ( 20 ) of the planetary gear ( 19 ) is the that the driven gear shaft ( 18 ) is passed through the driven gear shaft ( 12 ) and on it to the traction mechanism to the ring gear (1) has end facing a coaxial (20) arranged planetary carrier (22), that the driven pulley shaft (10) at its said gear transmission (2) facing the end of a koaxi al disposed to the ring gear (20), sun gear (21) has and that the sun gear ( 21 ) and the ring gear ( 20 ) mesh over little least one on the planet gear carrier ( 22 ) freely rotatably arranged planet gear ( 23 ) . 9. Torque converter according to one of claims 1-4 and 6, characterized in that it has a differential gear ( 24 ) which can be coupled with two impellers ( 30, 32 ). 10. Torque converter according to claim 9, characterized in that the differential gear ( 24 ) with the Überlagerungsge gear is combined. 11. Torque converter according to claim 10, characterized in that the differential ( 24 ) has four intermeshing differential gears ( 25 - 28 ), the inner half of the bevel gears ( 13 - 16 ) of the bevel gear differential gear ( 3 ) rectangle formed are arranged and of which a differential bevel gear ( 25 - 28 ) coaxially to one of the bevel gears ( 13 - 16 ) of the bevel gear differential gear ( 3 ) is arranged. 12. Torque converter according to claim 10, characterized in that the third differential bevel gear ( 27 ) and the four te differential bevel gear ( 28 ), the coaxial to the third bevel gear ( 15 ) and the fourth bevel gear ( 16 ) of the bevel gear differential gear ( 3 ) are arranged, freely rotatable on the connec tion axis ( 17 ) of these bevel gears ( 15, 16 ) that the first differential bevel gear ( 25 ), which is arranged coaxially with the most bevel gear ( 13 ), rotatably on an egg nem first impeller ( 30 ) detachable first output half-shaft ( 29 ) of the divided output shaft ( 18 ) is arranged that the second differential bevel gear ( 26 ), which is arranged coaxially to the second bevel gear ( 14 ), on which with a second impeller ( 32 ) Couplable second output half-shaft ( 31 ) is arranged, and that of the output half-shaft ( 29, 31 ), the first output half-shaft ( 29 ) through the output shaft shaft ( 10 ) designed as a hollow shaft and the zw From the drive half-shaft ( 31 ) through the drive shaft shaft ( 12 ) designed as a hollow shaft. 13. Torque converter according to claim 12, characterized in that the connecting axis ( 17 ) approximately centrally a Losla ger ( 33 ) through which the free end of the second drive half-shaft ( 31 ) freely rotatable and perpendicular to the connec tion axis ( 17 ) is and that the free end of the second output half-shaft ( 31 ) engages in a on the first from the same bevel gear ( 25 ) arranged bearing receptacle ( 34 ) freely rotating bar.