Patent Application
20100257962
This application claims priority from German patent application serial no. 10 2009 002 346.1 filed Apr. 14, 2009.
The present invention relates to a double clutch transmission.
A six or seven speed double clutch transmission is known from the published patent DE 103 05 241 A1. The double clutch transmission comprises two clutches each having their input side connected to the driveshaft, and their output side connected to one of the two transmission input shafts. The two transmission input shafts are disposed coaxially to each other. In addition, two countershafts are disposed axially parallel to the two transmission input shafts, whose idler gears mesh with fixed gears of the transmission input shafts. Furthermore, coupling devices that are axially movable are held in a rotationally fixed manner on the countershafts, in order to be able to shift to the respective toothed gearwheel. The respectively selected transmission ratio is transferred via the output gears to a differential. In order to realize the desired transmission ratio steps for the known double clutch transmissions, a plurality of gear planes is necessary such that significant construction space is required during installation.
Further, a spur-gear multi-speed transmission is known from the published patent DE 38 22 330 A1. The spur-gear multi-speed transmission comprises a double clutch transmission that can be shifted under load, and has one part is connected to driveshaft and an other part connected to a hollow driveshaft, this is rotatably supported on the driveshaft. The driveshaft can be coupled to the hollow driveshaft via a shift element for specific transmission ratios.
A power shift transmission with two clutches, which are each assigned a subtransmission, is known from the published patent DE 10 2004 001 961 A1. The transmission input shafts of the two subtransmissions are disposed coaxially to each other and via fixed gears mesh with idler gears of the associated countershafts. The respective idler gears of the countershafts can be connected to the respective countershaft in a rotationally fixed manner by means of the associated shift element. From this patent document, an eight speed transmission is known in which a further shift element is provided for coupling the two transmission input shafts in order to realize a further transmission ratio step. Even the eight speed transmission with this embodiment requires at least six gear planes in the two subtransmissions in order to realize the transmission ratio steps. This leads to an undesired elongation of the overall construction length in the axial direction such that the installation possibilities in a vehicle are severely restricted.
In addition, from the published patent DE 10 2005 028 532 A1, a further power shift transmission is known which comprises two input shafts and only one countershaft. A nine speed transmission in this embodiment requires, for example, at least seven gear planes in order be able to realize the transmission ratio steps. This leads to an undesired elongation of the overall construction length in the axial direction. In addition, for implementing the reverse gear transmission ratios, an additional shaft with a gear plane is required that comprises a shift element and two toothed gears. A further disadvantage results with the known power shift transmission in that power shifting is only possible between the first and second gear.
The present invention relates to the problem of proposing a double clutch transmission of the initially described type, in which multiple power shift transmission ratios are realized as cost-effectively as possible, and with as few components as possible, with a low construction space requirement.
Accordingly, a double clutch transmission that is optimized for construction space, having two clutches is proposed, whose input sides are connected to a driveshaft, and whose output sides are connected respectively to one of two transmission input shafts disposed coaxially to each other. The double clutch transmission comprises at least two countershafts or similar, on which toothed gearwheels formed as idler gears are mounted in a rotational manner, wherein toothed gearwheels, which mesh at least in part with the idler gears, are disposed on both transmission inputs shafts in a rotationally fixed manner, and are formed as fixed gears. Further, multiple coupling devices are provided for connection of an idler gear to a countershaft in a rotationally fixed manner. The double clutch transmission according to the invention has, in each case, an output gear or constant pinion, provided at each of the countershafts, that in each case, is coupled to gearing of a driveshaft to connect the respective countershaft to the output drive, and at least one shift element or similar that can be activated or engaged as a so-called winding path gear-shift element for the rotationally fixed connection of two toothed gearwheels, wherein at least multiple forward power shiftable gears and/or at least one reverse power shiftable gear are feasible.
The proposed double clutch transmission according to the invention preferably comprises only six gear planes, with which at least nine forward power shiftable gears can be realized with low construction space requirements.
For example, the six gear planes can be formed by at least three dual gear planes and three single gear planes, wherein in each dual gear plane respectively one idler gear of the first and second countershafts are assigned a fixed gear of one of the transmission input shafts, and at least one idler gear can be used for at least two gears, such that at least one power shiftable winding gear path can be shifted using at least one shift element. Other configurations are also possible.
Due to the possible multiple uses of idler gears with the proposed double clutch transmission, a maximum number of transmission ratios can be realized with the fewest possible gear planes, wherein preferably all forward gears can be power shifted in sequential implementation, and/or at least a reverse gear and at least a crawler gear can be power shifted.
To optimize the stepping with the proposed double clutch transmission according to the invention a dual gear plane can be replaced by two individual gear planes, in that one fixed gear is replaced by two fixed gears. Thereby, particularly harmonic, progressive gear stepping can be attained. It is also possible to replace two single gear planes by a dual gear plane.
The proposed double clutch transmission can preferably the implemented as a nine speed transmission with at least nine power shiftable gear steps. Due to the short construction compared to known transmission arrangements, the double clutch transmission according to the invention is particularly suited for a front transverse construction in a vehicle. However, other installations are also possible depending on the type and construction space of the respective vehicle in question. Preferably, with the proposed double clutch transmission, the ninth forward gear can be a winding path gear. Accordingly, the highest power shiftable gear can be a winding path gear. In addition, at least one reverse and/or further gears, for instance, crawler gears, can also be implemented as a winding path gear. Preferably, reverse gears are also implemented power shiftable among themselves.
As an example, depending on the embodiment, the first countershaft, for example, can be assigned three or four shiftable idler gears, and the second countershaft can be assigned five or six shiftable idler gears, which in each case mesh with fixed gears of the assigned transmission input shaft.
If the last or next-to-last gear increment is higher than the respectively previous one, a particularly high drive torque or drive power can be made available, in the event of a downshift requested by the driver.
In an advantageous manner with the double clutch transmission according to the invention, at most seven shift positions are necessary on a countershaft. In total, only 10 shift positions are used together on the two countershafts in order to realize the proposed gear steps.
According to the invention it, can be provided that by means of at least one shift element on the second countershaft, an idler gear of the second subtransmission can be connected to an idler gear of the first subtransmission, wherein via the shift element the ninth forward gear, and/or a reverse gear and/or at least a crawler gear can be shifted respectively as a winding path gear.
Furthermore, it can be provided by means of an alternate or additional shift element on the first countershaft, that the idler gear of the second subtransmission can be connected to the idler gear of the first subtransmission, so that via the shift element at least a reverse gear and/or at least a crawler gear can be shifted respectively as a winding path gear.
Consequently, using at least one shift element, with the double clutch transmission according to the invention, winding path gears can be realized, in which toothed gearwheels of both subtransmissions are coupled together in order to thereby realize a flow of power through both subtransmissions. Here, the shift element used in each case serves to couple two idler gears, and thereby brings the transmission input shafts into dependency on each other.
In the double clutch transmission, the arrangement of the shift elements for coupling of two specific idler gears can be varied so that the shift elements need not necessarily be disposed between the idler gears to be coupled. Accordingly, other arrangement positions of the respective shift elements are conceivable, in order to optimize, for example, linking to an actuator system.
With the double clutch transmission according to one possible embodiment, it can be provided that the first gear plane and the second gear plane respectively are single gear planes, and the third gear plane is a dual gear plane and comprise three fixed gears on the second transmission input shaft of the second subtransmission, wherein the fourth gear plane and the fifth gear plane in each case being dual gear planes and the sixth gear plane being a single gear plane comprise three fixed gears on the first transmission input shaft of the first subtransmission.
In the scope of a further variant embodiment of the invention, it can also be provided with the proposed double clutch transmission that the first gear plane being a single gear plane, and the second gear plane and the third gear plane respectively being dual gear planes, comprise three fixed gears on the second transmission input shaft of the second subtransmission, wherein the fourth gear plane being a single gear plane and the fifth gear plane being a dual gear plane and the sixth gear plane being a single gear plane comprise three fixed gears on the first transmission input shaft of the first subtransmission.
In order to provide the necessary reversal of rotation for implementing reverse gears with the double clutch transmission according to the invention, for example, at least one intermediate gear or similar can be used that is disposed e.g. on an intermediate shaft. It is also possible that one of the idler gears of a countershaft serves as an intermediate gear for at least one reverse gear. No additional intermediate shaft is necessary then for the reverse gear transmission ratio because one of the idler gears meshes both with a fixed gear as well as with a further shiftable idler gear of the other countershaft. Consequently, the intermediate gear required for the reverse gear is disposed as a shiftable idler gear on a countershaft, and serves to implement at least one further forward gear. The intermediate gear can also be implemented as a stepped gear independent of whether this is disposed on the counter shaft or on an additional intermediate shaft. Is also possible that the intermediate gear is not disposed on one of the countershafts that are already present, rather example, is provided on a further separate shaft, e.g. a third countershaft.
In order to obtain the desired transmission ratio steps it can be provided with the double clutch transmission according to the invention that at least one bidirectionally operative coupling device or similar is disposed at each countershaft. The provided coupling devices in the activated or engaged state, depending on the direction of actuation can connect an associated idler gear to the countershaft in a rotationally fixed manner. In addition, a unidirectionally operative coupling device or similar can also be disposed on at least one of the countershafts. As coupling devices, for example, hydraulically, electrically, pneumatically, or mechanically actuated clutches or also form-locking jaw clutches, as well as any type of synchronization, can be used, which serve for the rotationally fixed connection of an idler gear to a countershaft. It is also possible to replace a bidirectionally operative coupling device by two unidirectionally operative coupling devices or vice versa.
With the proposed double clutch transmission, it is conceivable that the specified arrangements of the toothed gear wheels vary, and also the number of toothed gearwheels as well as the number of coupling devices are changed in order to realize still further gears that can, or cannot, be power shifted, as well as to realize construction space savings and component savings. In particular, fixed gears of dual gear planes can be divided into two fixed gears for single gear planes. Thereby, step changes can be improved. In addition, it is also possible to interchange the countershafts. The subtransmissions can also be interchanged, i.e., mirrored about their vertical axes. In the process, hollow shafts and solid shafts are interchanged. Through this, it is possible to dispose the smallest gear on the solid shaft to further optimize the use of the existing construction space. Furthermore, adjacent gear planes can be interchanged to optimize a shaft deflection and/or to optimally connect a shift actuating system. In addition, the respective arrangement position of the coupling devices on the gear plane can be varied. Furthermore, the effective direction of the coupling devices can also be changed.
The gear numbering used here were freely defined. It is also possible to add a crawler or crawler gear and/or an overdrive or overdrive gear, in order to improve the off-road properties or the acceleration behavior of a vehicle. In addition a first gear can be omitted to better optimize the entirety of the step changes. The gear numbering varies correspondingly with these measures.
Independent of the respective variant embodiments of the double clutch transmission, the driveshaft and the output shaft can preferably be disposed non-coaxially to each other, which realizes a particularly construction space saving arrangement. For example, the shafts thus disposed spatially after each other, can also be offset slightly to each other. With this arrangement, a direct gear with a transmission ratio of one can be realized using meshing, and in an advantageous way can be placed relatively freely onto the sixth to ninth gear. Other arrangement possibilities of the driveshaft and the output shaft are also conceivable.
Preferably the proposed double clutch transmission is equipped with integrated output stages. The output stage can comprise a fixed gear on the output shaft as an output gear, which meshes with a first output gear as a fixed gear of the first countershaft, as well as with a second output gear as a fixed gear of the second countershaft. However it is also possible that at least one of the output gears is formed as a shiftable gear.
In an advantageous manner, the lower forward gears and the reverse gears can be actuated using a startup clutch or shifting clutch, to consequently concentrate higher loads onto this clutch, and with it, to be able to implement the second clutch in a more cost-effective and construction space saving manner. In particular, the gear planes with the proposed double clutch transmission can be disposed such that start-up is possible via the inner transmission input shaft or also the outer transmission input shaft, and thus via the respectively better suited clutch, which is also enabled with a concentrically arranged, radially shifted, nested construction of the double clutch. In addition, the gear planes can be disposed correspondingly mirror symmetrical or interchanged.
Independent of the respective variant embodiment of the double clutch transmission, the provided gear planes, for example, can be interchanged.
The present invention is described in the following in more detail with reference to the drawings. They show:
The
The nine speed double clutch transmission comprises two clutches K1, K2 whose input sides are connected to a driveshaft w_an, and whose output sides are respectively connected to one of two transmission input shafts w_k1, w_k2, disposed coaxially to each other. In addition, a torsional vibration damper 22 can be disposed on the driveshaft w_an. Furthermore, two countershafts w_v1, w_v2 are provided, on which toothed gearwheels formed as idler gears 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18 are mounted in a rotational manner. Toothed gear wheels formed as fixed gears 1, 2, 3, 4, 5, 6 that connected to the two transmission input shafts w_k1, w_k2 in a rotationally fixed manner, mesh at least in part with the idler gears 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18. In order to be able to connect the idler gears 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18 to the respective countershaft w_v1, w_v2, multiple coupling devices B, C, D, E, F, G, H, I, J, K, L that can be activated are provided on the countershafts w_v1, w_v2. Furthermore, output gears 20, 21 are disposed on the two countershafts w_v1, w_v2 as constant pinions, which are, in each case, coupled to gearing of a fixed gear 19 of a output shaft w_ab.
Along with the coupling devices B, C, D, E, F, G, H, I, J, K, L which realize a rotationally fixed connection between a toothed gear wheel and the associated countershaft w_v1, w_v2, with the double clutch transmission at least one winding path gear-shift element M, N is provided for a rotationally fixed connection of two toothed gear wheels of a countershaft w_v1, w_v2, so that at least one winding path gear is realized.
According to the invention in the double clutch transmission only six gear planes 1-13, 2-14, 8-14, 9-15, 4-16, 10-16, 11-17, 12-6, 6-18 are provided, wherein for each variant embodiment three dual gear planes 8-14, 9-15, 10-16, 11-17 and three single gear planes 1-13, 2-14, 4-16, 12-6, 6-18 are provided, so that at least a power shiftable winding path gear can be shifted via at least one activated shift element M, N. As a shift element M, N, in each case, e.g., a pawl or similar can be used for the connection of two gears.
In all variant embodiments of the invention, the shift element N is, in each case, disposed on the second countershaft w_v2 to connect the idler gear 15 to the idler gear 16, when the shift element N is activated. Preferably, in one or also in several variant embodiments, in each case, an additional shift element M can be provided on the first countershaft w_v1 to realize further winding path gears. With the activated shift element M, the idler gears 9 and 10 can be connected together in a rotationally fixed manner.
In all variant embodiments according to the
For the third gear plane 9-15 as a dual gear plane, in all variant embodiments, the fixed gear 3 of the second transmission input shaft wk2 meshes with both the idler gear 15 of the second countershaft w_v2 and the idler gear 9 of the first countershaft w_v1. In the first variant embodiment according to
According to the second, fourth and fifth variant embodiments, with the fourth gear plane 10-16 as a dual gear plane, the fixed gear 4 of the first transmission input shaft w_k1 meshes with both the idler gear 10 of the first countershaft w_v1 as well as with the idler gear 16 of the second countershaft w_v2. With the third variant embodiment according to
In the first and third variant embodiments according to the
According to the second, fourth and fifth variant embodiments according to the
In all variant embodiments, a single acting coupling device G is assigned on the second countershaft w_v2 of the first gear plane 1-13; with this coupling device, the idler gear 13 is connected to the second countershaft w_v2 in a rotationally fixed manner, when the coupling device G is activated. Furthermore, a dual acting coupling device H-I is provided on the second countershaft w_v2 between the second gear plane 2-14 or 8-14 and the third gear plane 9-15. If the coupling device H is activated, the idler gear 14 can be connected with the second countershaft w_v2 in a rotationally fixed manner. If, in contrast, the coupling device I is activated, the idler gear 15 can be connected with the second countershaft w_v2 in a rotationally fixed manner. Finally, for all variant embodiments, a dual acting coupling device J-K is also provided between the fourth gear plane 10-16 or 4-16 and the fifth gear plane 11-17. If the coupling device J is activated, the idler gear 16 is connected to the second countershaft w_v2 in a rotationally fixed manner, and when the coupling device K is activated, the idler gear 17 is connected to the second countershaft w_v2 in a rotationally fixed manner.
For the fourth variant embodiment according to
In the first, second, fourth and fifth variant embodiments according to the
In the third variant embodiment according to
In the double clutch transmission according to the invention, an integrated output stage can be provided with the output gear 20, which is connected to the first countershaft w_v1 in a rotationally fixed manner, and with the output gear 21, which is disposed on the second counter shaft w_v2. The output gear 20 and the output gear 21 each mesh with a fixed gear 19 of the output shaft w_ab. However, it is also possible that a shiftable connection is implemented between the output gear 20 or 21 and the associated countershaft w_v1 or w_v2.
Independent of the respective variant embodiment, with the double clutch transmission according to the invention it is feasible that at least the forward gears G1 to G9 can be power shifted. Depending on the variant embodiment, additionally, reverse gears and/or crawler gears are also implemented as power shiftable winding path gears. Details for each variant embodiment arise from the shifting schemes described in the following.
The table in
It can be seen from the shifting scheme that the first forward gear G1 can be shifted using the first clutch K1 and using the activated coupling device E, that the second forward gear G2 can be shifted using the second clutch K2 and using the activated coupling device C, that the third forward gear G3 can be shifted using the first clutch K1 and using the activated coupling device K, that the fourth forward gear G4 can be shifted using the second clutch K2 and using the activated coupling device I, that the fifth forward gear G5 can be shifted using the first clutch K1 and using the activated coupling device J, that the sixth forward gear G6 can be shifted using the second clutch K2 and using the activated coupling device H, that the seventh forward gear G7 can be shifted using the first clutch K1 and using the activated coupling device F, that the eighth forward gear G8 can be shifted using the second clutch K2 and using the activated coupling device G, and that the ninth forward gear G9 can be implemented as a winding path gear using the first clutch K1 and using the activated coupling device G as well as using the activated shift element N.
With the first variant embodiment, it can be seen further from the table in
Beyond this, with the proposed double clutch transmission according to the first variant embodiment, a crawler gear C1 can be shifted as a winding path gear using the second clutch K2, using the activated coupling device E, and using the activated shift element N. In advantageous manner, power shifting between the first crawler gear C1 and the first forward gear G1 can occur under load, i.e., without interruption of the tractive force. (C1 lsp. to G1).
The table in
It can be seen from the shifting scheme that the first forward gear G1 can be shifted using the first clutch K1 and using the activated coupling device E, that the second forward gear G2 can be shifted using the second clutch K2 and using the activated coupling device H, that the third forward gear G3 can be shifted using the first clutch K1 and using the activated coupling device F, that the fourth forward gear G4 can be shifted using the second clutch K2 and using the activated coupling device I, that the fifth forward gear G5 can be shifted using the first clutch K1 and using the activated coupling device J, that the sixth forward gear G6 can be shifted using the second clutch K2 and using the activated coupling device C, that the seventh forward gear G7 can be shifted using the first clutch K1 and using the activated coupling device D, that the eighth forward gear G8 can be shifted using the second clutch K2 and using the activated coupling device G, and that the ninth forward gear G9 can be implemented as a winding path gear using the first clutch K1 and using the activated coupling device G as well as using the activated shift element N.
With the second variant embodiment, it can further be seen from the table in
Furthermore, a crawler gear C1 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device E, as well as using an activated shift element M. Beyond that, a crawler gear C2 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device E, as well as using an activated shift element N. Both crawler gears C1, C2 can be power shifted to the first forward gear G1.
In addition, an overdrive gear O1 can be shifted as a winding path gear using the first clutch K1 and using the activated coupling device G, as well as using an activated shift element M.
The table in
It can be seen from the shifting scheme that the first forward gear G1 can be shifted using the first clutch K1 and using the activated coupling device F, that the second forward gear G2 can be shifted using the second clutch K2 and using the activated coupling device H, that the third forward gear G3 can be shifted using the first clutch K1 and using the activated coupling device E, that the fourth forward gear G4 can be shifted using the second clutch K2 and using the activated coupling device C, that the fifth forward gear G5 can be shifted using the first clutch K1 and using the activated coupling device K, that the sixth forward gear G6 can be shifted using the second clutch K2 and using the activated coupling device I, that the seventh forward gear G7 can be shifted using the first clutch K1 and using the activated coupling device J, that the eighth forward gear G8 can be shifted using the second clutch K2 and using the activated coupling device G, and that the ninth forward gear G9 can be implemented as a winding path gear using the first clutch K1 and using the activated coupling device G as well as using the activated shift element N.
With the third variant embodiment, it can further be seen from the table in
Furthermore, a crawler gear C1 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device F, as well as using the activated shift element N. The crawler gear C1 can be power shifted to the first forward gear G1.
The table in
It can be seen from the shifting scheme that the first forward gear G1 can be shifted using the first clutch K1 and using the activated coupling device E, that the second forward gear G2 can be shifted using the second clutch K2 and using the activated coupling device H, that the third forward gear G3 can be shifted using the first clutch K1 and using the activated coupling device L, that the fourth forward gear G4 can be shifted using the second clutch K2 and using the activated coupling device C, that the fifth forward gear G5 can be shifted using the first clutch K1 and using the activated coupling device D, that the sixth forward gear G6 can be shifted using the second clutch K2 and using the activated coupling device I, that the seventh forward gear G7 can be shifted using the first clutch K1 and using the activated coupling device J, that the eighth forward gear G8 can be shifted using the second clutch K2 and using the activated coupling device G, and that the ninth forward gear G9 can be implemented as a winding path gear using the first clutch K1 and using the activated coupling device G as well as using the activated shift element N.
With the fourth variant embodiment, it can further be seen from the table in
Beyond this, with the proposed double clutch transmission according to the fourth variant embodiment, a crawler gear C1 can be shifted as a winding path gear using the second clutch K2, using the activated coupling device E, and using the activated shift element M. In addition, a further crawler gear C2 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device E, as well as using an activated shift element N. The crawler gears C1, C2 can be power shifted to the first forward gear G1.
The table in
It can be seen from the shifting scheme that the first forward gear G1 can be shifted using the first clutch K1 and using the activated coupling device E, that the second forward gear G2 can be shifted using the second clutch K2 and using the activated coupling device H, that the third forward gear G3 can be shifted using the first clutch K1 and using the activated coupling device F, that the fourth forward gear G4 can be shifted using the second clutch K2 and using the activated coupling device C, that the fifth forward gear G5 can be shifted using the first clutch K1 and using the activated coupling device D, that the sixth forward gear G6 can be shifted using the second clutch K2 and using the activated coupling device I, that the seventh forward gear G7 can be shifted using the first clutch K1 and using the activated coupling device J, that the eighth forward gear G8 can be shifted using the second clutch K2 and using the activated coupling device G, and that the ninth forward gear G9 can be implemented as a winding path gear using the first clutch K1 and using the activated coupling device G as well as using the activated shift element N.
With the fifth variant embodiment, it can further be seen from the table in
Furthermore, a crawler gear C1 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device E, as well as using an activated shift element M. Beyond that, a further crawler gear C2 can be shifted as a winding path gear using the second clutch K2 and using the activated coupling device E, as well as using an activated shift element N. The crawler gears C1 and C2 can be power shifted to the first forward gear G1 (C1, C2 lsb. to G1).
From the shift pattern according to
From the shift pattern according to
Furthermore, for the further crawler gear C1, based on the second clutch K2, the gear stages i_6, i_7 and i_1 are used, wherein the two subtransmissions are coupled using a shift element M. For the crawler gear C2, based on the second clutch K2, the gear stages i_4, i_5 and i_1 are used, wherein the shift element N is used for coupling the two subtransmissions. Finally, for the overdrive gear O1, based on the first clutch K1, the gear stages i_7, i_6 and i_8 are used, wherein the two subtransmissions are coupled using a shift element M.
From the shift pattern according to
From the shift pattern according to
From the shift pattern according to
In summary, for the first and second variant embodiments according to the
Further, with the first variant embodiment according to
In detail, the first variant embodiment results in that on the first gear plane 1-13 as a single gear plane, that the idler gear 13 is used for two forward gears G8, G9. On the second gear plane 2-14 as a single gear plane, the idler gear 14 is used for a forward gear G6. On the third gear plane 9-15 as a dual gear plane, the idler gear 9 is used for a forward gear G2 as well as for a reverse gear R2, and the idler gear 15 is used for three forward gears G4, G9, C1 as well as for a reverse gear R3. On the fourth gear plane 10-16 as a dual gear plane, the idler gear 10 is used for three reverse gears R1, R2, R3, and the idler gear 16 is used for three forward gears G5, G9, C1 as well as for a reverse gear R3. On the fifth gear plane 11-17 as a dual gear plane, the idler gear 11 is used for two forward gears G1, C1 as well as for a reverse gear R2, and the idler gear 17 is used for a forward gear G3. Finally, on the sixth gear plane 12-6 as a single gear plane, the idler gear 12 is used for the forward gear G7.
In summary, the second variant embodiment according to the
In detail, the second variant embodiment results in that on the first gear plane 1-13 as a single gear plane, the idler gear 13 is used for three forward gears G8, G9, O1. On the second gear plane 2-14 as a single gear plane, the idler gear 14 is used for a forward gear G2. On the third gear plane 9-15 as a dual gear plane, the idler gear 9 is used for three forward gears G6, C1, O1 as well as for a reverse gear R2, and the idler gear 15 is used for three forward gears G4, G9, C2 as well as for a reverse gear R3. On the fourth gear plane 10-16 as a dual gear plane, the idler gear 10 is used for three forward gears G7, C1, O1 as well as for a reverse gear R2, and the idler gear 16 is used for three forward gears G5, G9, C2 as well as for a reverse gear R3. On the fifth gear plane 11-17 as a dual gear plane, the idler gear 11 is used for three forward gears G1, C1, C2, and the idler gear 17 is used for three reverse gears R1, R2, R3. Finally, on the sixth gear plane 12-6 as a single gear plane, the idler gear 12 is used for a forward gear G3.
In summary, with the third, fourth and fifth variant embodiments according to the
In addition, with the third variant embodiment according to the
In detail, the third variant embodiment results in that on the first gear plane 1-13 as a single gear plane, that the idler gear 13 is used for two forward gears G8, G9. On the second gear plane 8-14 as a dual gear plane, the idler gear 8 is used for two reverse gears R1, R2, and the idler gear 14 is used for a forward gear G2. On the third gear plane 9-15 as a dual gear plane, the idler gear 9 is used for a forward gear G4, and the idler gear 15 is used for three forward gears G6, G9, C1 as well as for a reverse gear R2. On the fourth gear plane 4-16 as a single gear plane, the idler gear 16 is used for three forward gears G7, G9, C1 as well as for a reverse gear R2. On the fifth gear plane 11-17 as a dual gear plane, the idler gear 11 is used for a forward gear G3, and the idler gear 17 is used for a forward gear G5. Finally, on the sixth gear plane 12-6 as a single gear plane, the idler gear 12 is used for two forward gears G1, C1.
In summary, the fourth variant embodiment according to the
In detail, the fourth variant embodiment results in that on the first gear plane 1-13 as a single gear plane, the idler gear 13 is used for two forward gears G8, G9. On the second gear plane 2-14 as a single gear plane, the idler gear 14 is used for a forward gear G2. On the third gear plane 9-15 a dual gear plane, the idler gear 9 is used as for two forward gears G4, C1, as well as for a reverse gear R3, and the idler gear 15 is used for three forward gears G6, G9, C2 as well as for a reverse gear R2. On the fourth gear plane 10-16 as a dual gear plane, the idler gear 10 is used for two forward gears G5, C1 as well as for a reverse gear R3, and the idler gear 16 is used for three forward gears G7, G9, C2 as well as for a reverse gear R2. On the fifth gear plane 11-17 as a dual gear plane, the idler gear 11 is used for three forward gears G1, C1, C2, and the idler gear 17 is used for three reverse gears R1, R2, R3. Finally, on the sixth gear plane 6-18 as a single gear plane, the idler gear 18 is used for a forward gear G3.
In summary, the fifth variant embodiment according to the
In detail, the fifth variant embodiment results in that on the first gear plane 1-13 as a single gear plane, the idler gear 13 is used for two forward gears G8, G9. On the second gear plane 2-14 as a single gear plane, the idler gear 14 is used for a forward gear G2. On the third gear plane 9-15 as a dual gear plane, the idler gear 9 is used for two forward gears G4, C1 as well as for a reverse gear R2, and the idler gear 15 is used for three forward gears G6, G9, C2 as well as for a reverse gear R3. On the fourth gear plane 10-16 as a dual gear plane, the idler gear 10 is used for two forward gears G5, C1 as well as for a reverse gear R2, and the idler gear 16 is used for three forward gears G7, G9, C2 as well as for a reverse gear R3. On the fifth gear plane 11-17 as a dual gear plane, the idler gear 11 is used for three forward gears G1, C1, C2, and the idler gear 17 is used for three reverse gears R1, R2, R3. Finally, on the sixth gear plane 12-6 as a single gear plane, the idler gear 12 is used for the forward gear G3.
It is possible with one or several of the variant embodiments that at least one additional gear stage or an intermediate step gear is used for winding path gears, which is/are not used in a direct gear.
With all variant embodiments of the double clutch transmission, due to the provided multiple uses of individual idler gears, fewer gear planes, and thus fewer components are necessary for the same number of gears, resulting in an advantageous cost savings and construction space savings.
Independent of the respective variant embodiment, the number “1” in a field of the respective table of the shift pattern according to the
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2009 002 346.1 | Apr 2009 | DE | national |
