A transmission unit (1), particularly for a wind power plant, which has a first planetary stage (2), on the drive input side, a second planetary stage (3) and a third planetary stage (4), on the drive output side, which are coupled with one another in such a manner that a torque from the drive input side can be divided between the first and the second planetary stages (2; 3) and recombined in the third planetary stage (4). The first, the second and the third planetary stages (2; 3; 4) have a common gearwheel carrier (20) which is mounted for rotation about a rotational axis of the transmission unit (1).

The present invention relates to a Self-Governed Gear Box (SGGB) functions as an automatic gear box system suitable for any power drive ranging from electrical to mechanical. This is an optimally-performed gear box system, in terms of power loss. The assembly is compact and simple with no additional elements other than gears. For the same reason, it is highly economical, easy to assemble and easy to maintain, with an expected ideal performance. Such a dynamic task of an automatic gear box system is achieved by implementing an algorithm enabling to sense the additional load applied at the input end, created by diverting a small quantity of power from the output end. This is in effect of inducing an engine disturbance as under-drive, under sub-optimum output rpm-torque conditions. As the engine disturbance introduced for sub-optimum output rpm-torque condition is a continuous governance mechanism, the input to output speed ratio assumed also will be continues in a designed range. The engine starts from zero speed when this gear box system is coupled between an engine and a load. Thus it is a continuously variable transmission system.

An electric portal axle (1) for electrically driving a motor vehicle has a housing (28), a single electric machine (2) and two spur gear stages (13, 14) for driving two wheels of the axle. A shiftable transmission (5) is downstream of the electric machine (2) and is embodied as a planetary gear mechanism with a freewheel (6) and a differential (7). The portal axle (1) has a shifting mechanism (23) for shifting two gear stages of the portal axle (1). In a first gear stage, a ring gear (9) of the transmission (5) and a clutch body (27) that is fixed to the housing are connected, and a clutch (29) between the ring gear (9) and a planetary carrier (11) of the transmission (5) is opened. In a second gear stage the ring gear (9) and the clutch body (27) are disconnected and the clutch (29) is closed.

A motor vehicle transmission having main group and a range group that is connected downstream from the main group which has a planetary stage with transmission components. A first component couples an output shaft of the range group and a second component couples an output shaft of the main group. A third component can couple a housing and the first or the second components. For carrying out a range shift of the range group, which cannot be shifted under load, and to enable an arrangement of gear steps of the upstream main group, the drive output shaft passes axially through the planetary stage to the main group. The output shaft is a central shaft with which the input shaft of the main group can be connected in a rotationally fixed manner, and over which the output shaft of the main group is positioned as a coaxially extending hollow shaft.

Provided is a power transmitting device including an input side gear assembly that includes a single power input terminal and two power output terminals, an output side gear assembly that includes two power input terminals and a single power output terminal, the two power input terminals configured to operate using power received from the two power output terminals of the input side gear assembly, respectively, and a stopper module configured to block power to be transmitted through one of two power transmitting paths connecting the two power output terminals of the input side gear assembly and the two power input terminals of the output side gear assembly.

A transmission includes a single planetary gearset, a first torque machine, an output member and a two-speed gearset that is coupled to the drive member. The single planetary gearset includes a sun gear, a carrier gearset and a ring gear, wherein the carrier gearset is rotatably couplable to the input member and rotatably couplable to the output member, the sun gear is rotatably coupled to a rotor of the first torque machine, and the ring gear is rotatably couplable to the input member and rotatably couplable to the output member. The output member is rotatably couplable to the two-speed gearset, which is configured to operate in one of a first gear ratio and a second gear ratio.

A system for hydraulically coupled multi-variator actuation is disclosed. One system includes: a first hydraulic variator comprising: a first hydraulic pump; and a first hydraulic motor linked to the first hydraulic pump. The system may further include a second hydraulic variator comprising: a second hydraulic pump; and a second hydraulic motor linked to the second hydraulic pump. The system may further include a first actuator linked to the first hydraulic pump and configured to control a displacement of the first hydraulic pump; a second actuator linked to the second hydraulic pump and configured to control a displacement of the second hydraulic pump; a hydraulic link connecting the first actuator and the second actuator, the hydraulic link configured to facilitate a coordinated operation of the first actuator and the second actuator; a valve disposed in fluid communication with the hydraulic link connecting the first actuator and the second actuator; and a controller connected to the valve and configured to control an operation of the valve to regulate hydraulic flow in the hydraulic link.

The invention is directed to a freewheel mechanism comprising: a) an input shaft, which rotates at an input speed; b) an output shaft, which rotates at an output speed; c) a first differential-gear or planetary-gear system, which is arranged between the two shafts and comprises at least one toothed orbital or planetary gear, which is rotatably mounted in a first orbital-gear or planetary-gear carrier and meshes with two internal toothed rings on two further rotary connections of the first differential-gear or planetary-gear system, the speeds thereof determining the speed of the first orbital-gear or planetary-gear carrier in the first differential-gear or planetary-gear system; d) a second differential-gear or planetary-gear system, which comprises at least one toothed orbital or planetary gear, which is rotatably mounted in a second orbital-gear or planetary-gear carrier and meshes with two internal toothed rings on two further rotary connections of the second differential-gear or planetary-gear system, the speeds thereof determining the speed of the second orbital-gear or planetary-gear carrier in the second differential-gear or planetary-gear system; and e) a housing, in which both or all the differential-gear or planetary-gear systems are accommodated.

A control apparatus for a dynamic power transmission apparatus is provided. The dynamic power transmission apparatus includes a differential mechanism, an electric generator, an electric motor, and a fluid coupling. The electric motor is disposed at a position apart from a transmission path along which a dynamic power of an engine is transmitted to a driving wheel. The fluid coupling is disposed between the electric motor and the transmission path. The control apparatus includes an electronic controller configured to restrict a charge of an electric storage apparatus with an electric power generated by the electric generator, depending on a state of the electric storage apparatus, and control the fluid coupling to differentially rotate and to drive the electric motor by the electric power such that a dynamic power loss is generated in the fluid coupling, when restricting the charge of the electric storage apparatus.

Methods and systems are provided for a transmission. In one example, a system includes a shifting mechanism arranged between a first planetary gearset and a second planetary gearset arranged in series, wherein the shifting mechanism is configured to adjust an operating mode to a first mode, a second mode, or a tow mode.