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.

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.

There is provided an automatic transmission capable of preventing deterioration of driving performance even when an engagement mechanism is not switched due to a failure. An automatic transmission includes a first brake which is always in a fixed state from a first forward gear stage to a predetermined gear stage and is in an open state at a gear stage with a higher speed than the predetermined gear stage, and a hydraulic sensor configured to detect whether the first brake is switched to the fixed state. When a transmission control device instructs the first brake to switch to the fixed state, and it is confirmed that the first brake is in an open state, the transmission control device instructs engagement mechanisms other than the first brake to perform switching so that a preliminary gear stage is able to be set.

A mechanically actuated level control valve device for a commercial vehicle with an air suspension system is a level control valve and comprises a drive element that can be mechanically coupled to a vehicle wheel or axle. A valve element and a counter valve element have a first relative position, wherein the port for the air suspension bellow is closed, a second relative position, wherein the port for the air suspension bellow is connected to the port for the aeration device, and a third relative position, wherein the port for the air suspension bellow is connected to the port for the deaeration device. The valve element is coupled to a rotatable driveshaft of the level control valve by a drive mechanism. An integrated actuator changes the relative position of the valve element and the drive element or the relative position of the counter valve element and a valve housing.

A mechanically actuated level control valve device for a commercial vehicle with an air suspension system is a level control valve and comprises a drive element that can be mechanically coupled to a vehicle wheel or axle. A valve element and a counter valve element have a first relative position, wherein the port for the air suspension bellow is closed, a second relative position, wherein the port for the air suspension bellow is connected to the port for the aeration device, and a third relative position, wherein the port for the air suspension bellow is connected to the port for the deaeration device. The valve element is coupled to a rotatable driveshaft of the level control valve by a drive mechanism. An integrated actuator changes the relative position of the valve element and the drive element or the relative position of the counter valve element and a valve housing.

A camera arm of a camera-based mirror substitute system for a motor vehicle comprises a first structural element for connecting the camera arm to a motor vehicle and a second structural element which comprises at least one camera, the second structural element being pivotable in relation to the first structural element. In order to provide a fastening for cameras of camera monitor systems for mirror substitution in motor vehicles, said fastening offering improved protection against external damaging influences on the fastening and on all elements, devices and modules, in particular cameras, arranged thereon, and enabling an optimum image area of the camera, it is proposed that the second structural element and the first structural element are connected to one another by way of a pivoting mechanism, the pivoting mechanism comprising a planetary gearing.

A camera arm of a camera-based mirror substitute system for a motor vehicle comprises a first structural element for connecting the camera arm to a motor vehicle and a second structural element which comprises at least one camera, the second structural element being pivotable in relation to the first structural element. In order to provide a fastening for cameras of camera monitor systems for mirror substitution in motor vehicles, said fastening offering improved protection against external damaging influences on the fastening and on all elements, devices and modules, in particular cameras, arranged thereon, and enabling an optimum image area of the camera, it is proposed that the second structural element and the first structural element are connected to one another by way of a pivoting mechanism, the pivoting mechanism comprising a planetary gearing.

A planetary gear train of an automatic transmission for a vehicle includes input and output shafts, and first, second, third, fourth, and fifth planetary gear sets, each including three rotational elements. The gear train also includes nine shafts for selectively connecting the planetary gear sets, the input and output shafts, and a transmission housing in various configurations to achieve at least ten forward speeds and at least one reverse speed.

Methods of modifying a OE prior art transmission, including Ford's AOD, AODE and 4R70W transmissions, to strengthen the transmission by replacing components known to fail. In one example, the intermediate shaft and direct clutch cylinder of an OE transmission are replaced to eliminate the splined connection joining the two components, to simultaneously eliminate the weak splined connection while also making space within the transmission available for an increased diameter shaft. Aspects of the present disclosure also include kits for increasing the strength of a transmission and methods of assembling a transmission.

Methods of modifying a OE prior art transmission, including Ford's AOD, AODE and 4R70W transmissions, to strengthen the transmission by replacing components known to fail. In one example, the intermediate shaft and direct clutch cylinder of an OE transmission are replaced to eliminate the splined connection joining the two components, to simultaneously eliminate the weak splined connection while also making space within the transmission available for an increased diameter shaft. Aspects of the present disclosure also include kits for increasing the strength of a transmission and methods of assembling a transmission.