Abstract: A hydrostatic driveline has a power source, a transmission portion, a hydrostatic pump, a hydrostatic motor, a transfer case, a first axle assembly, an inter-axle drive shaft, and a second axle assembly. The transmission portion is drivingly engaged with the power source. The hydrostatic pump is in driving engagement with the transmission portion. The hydrostatic motor is in fluid communication with the hydrostatic pump. The transfer case is in driving engagement with the hydrostatic motor. The inter-axle drive shaft is in driving engagement with the transfer case and the transmission portion. The transmission portion, the hydrostatic pump, the hydrostatic motor, the transfer case, and the inter-axle shaft form a first power path for the hydrostatic driveline and the transmission portion and the inter-axle shaft form a second power path for the hydrostatic driveline.

Abstract: Systems, devices, and methods are provided for the transmission of power in motor vehicles. Power can be transmitted in a smoother and more efficient manner, with smaller and even less mechanical components, by splitting torque into two or more torque paths. A power transmission apparatus comprises a power input shaft, a planetary gear set coupled to the power input shaft, and a variator, such as a continuously variable transmission (CVT), coupled to the gear set. The various components of the planetary gear set and the variator are arranged such that torque is split between two or more torque paths and then recombined before power is output to a gear box and a differential of the motor vehicle.

Abstract: A waste heat recovery system for use with a cooling system of an internal combustion engine is provided. The waste heat recovery system comprises a condenser, a pump, a fluid reservoir, a heat exchanger, an expansion device, and an auxiliary cooling device. The condenser is in thermal communication with the cooling system of the internal combustion engine. The heat exchanger is in fluid communication with the pump and thermal communication with an exhaust of the internal combustion engine. The expansion device is in fluid communication with the heat exchanger and the condenser. The auxiliary cooling device is in fluid communication with at least one of the condenser, the expansion device, and the fluid reservoir. In response to an effectiveness of the condenser in dissipating heat from the waste heat recovery system to the cooling system of the internal combustion engine, the auxiliary cooling device is selectively actuated.

Abstract: A waste heat recovery system and control system and method of controlling a waste heat recovery system and control system is provided. The waste heat recovery system and control system comprises a pump, a heat exchanger, an expansion device, a condenser, a plurality of sensors, and a controller. The heat exchanger is in thermal communication with an exhaust of the internal combustion engine. The condenser is in thermal communication with the expansion device and the pump. The plurality of sensors is in communication with the waste heat recovery system. The controller is in communication with the plurality of sensors. In response to information obtained from the plurality of sensors, the controller calculates an efficiency of the waste heat recovery system based on models of the waste heat recovery system and implements a set of control inputs to implement the calculated efficiency on the waste heat recovery system.

Abstract: A system and a method for data collection and analysis that uses a multi-level network are provided. The system comprises a first client device and a central network. The first client device and the central network form the multi-level network. The first client device is configured to receive a first data and perform a first data fusing process based on the first data. The first data fusing process generates a second data. The central network is in communication with the first client device. The central network receives the second data from the first client device. The central network is configured to perform a second data fusing process based on the second data to generate a third data. The third data is communicated to the first client device so that the first client device can perform a third data fusing process based on the third data to generate a fourth data.

Abstract: A variable transmission includes an input shaft, two planetary gear sets, a first planetary set on the input side of a variator, and a second planetary set on the output side of the variator, to split the torque drivingly engaged with a variator comprising, a first ring assembly, a second ring assembly; various arrangements of brakes and clutches; a gearbox; and the output shaft to produce transmissions with continuously variable or infinitely variable torque output ratios.

Abstract: A transmission having a variator drive capable of being placed in a continuously variable operating mode or an infinitely variable operating mode, capable of having a wide ratio range, and capable of integrating a clutching capability within the transmission. The variable transmissions can be operated in at least two different operating modes, depending on an engagement status of the clutches therein. Methods of running the variable transmissions and drivelines that incorporate such variable transmissions are provided.

Abstract: A transmission is provided. The transmission includes an input portion drivingly engaged with a power source, a planetary gear, a continuously variable variator, and a clutching device. The planetary gear arrangement has a portion drivingly engaged with the input portion. The continuously variable variator includes a portion which is drivingly engaged with at least one of the planetary gear arrangement and the input portion. The clutching device may be selectively drivingly engaged with a portion of the continuously variable variator. The clutching device and the planetary gear arrangement facilitate a transition between at least two operating modes of the continuously variable variator.

Abstract: The inventors' findings relate to a transmission for vehicles, comprising an input side configured for being coupled to a prime mover and an output side configured for being coupled to a driven element wherein the transmission comprises an electromagnetic torque converter (EMTC), wherein the EMTC has at least two output paths, namely the first output path coupled to a gear box which is preferably configured for being coupled to a drive shaft of the vehicle, and a second output path which is configured to be coupled to an auxiliary power provider. The inventors' findings also relate to a vehicle driveline comprising said transmission. Furthermore, the inventors' findings also relate to a vehicle comprising said vehicle driveline.

Abstract: A variable transmission includes an input shaft, a planetary gear set drivingly engaged with a variator comprising, a variator carrier assembly, a first ring assembly, and a second ring assembly; and the output shaft, arranged with various combinations of brakes and clutches to produce transmissions with continuously variable or infinitely variable torque output ratios.

Abstract: A hydrostatic driveline is provided. The hydrostatic driveline comprises a power source, a hydrostatic pump, a hydrostatic motor, a direct drive link, and a transmission portion. The power source is drivingly engaged with an input member. The hydrostatic pump is in driving engagement with the input member. The hydrostatic motor is in fluid communication with the hydrostatic pump. The direct drive link is in driving engagement with the input member. The transmission portion is in driving engagement with a vehicle output and at least one of the hydrostatic motor and the direct drive link The transmission portion includes at least one engagement device and a drive ratio. The hydrostatic pump, the hydrostatic motor, and the transmission portion form a first power path for the hydrostatic driveline and the direct drive link forms a second power path for the hydrostatic driveline.

Abstract: A turbocharger for use with an internal combustion engine is provided. The turbocharger comprises a differential device having a carrier portion, a compressor portion, and a turbine portion. The compressor portion is in driving engagement with a first portion of the differential device. The turbine portion is in driving engagement with a second portion of the differential device. The carrier portion of the differential device is in driving engagement with an infinitely variable transmission. The infinitely variable transmission is in driving engagement with the internal combustion engine. The turbocharger is simply controlled, reduces turbo lag, decreases a boost threshold of the turbocharger, and increases an efficiency of the internal combustion engine.

Abstract: A system for monitoring torque input into a transmission from a torque source comprising a torque sensing device and a control mechanism. The torque sensing device adapted to transfer torque from the torque source to the transmission input while measuring said torque. The control mechanism may be adapted to control the transmission in order to prevent damage from a high torque situation.

Abstract: A variable transmission includes various powerpath layouts consisting in either; a single mode with approximately symmetrical reverse and forward speeds and includes an input shaft, one or two planetary gear sets, or a planetary gear set and a compound gear set when the RTS (ring-to-sun) ratio of the planetary gear set is not physically possible; or a dual mode with each mode being selected by closing a clutch/brake and releasing the other. A first up-speed planetary gear set on the input side of a variator, and a second planetary gear set on the output side of the variator, both configured to split the torque when drivingly engaged with a variator comprising, a first ring assembly, and a second ring assembly. Various up-speed ratio arrangements are shown that tend to increase the speeds and decrease the torque acting on the CVP, allowing a decrease in the variator size.

Abstract: A system and method for determining a remaining useful life of a portion of a wet clutch system is provided. The system comprises a first clutch assembly, a proportional valve, a sensor, and a controller. The proportional valve regulates a pressure applied to the first clutch assembly. The sensor measures a response of the first clutch assembly during one of engaging and disengaging a first portion of the first clutch assembly with a second portion of the first clutch assembly. The controller controls the proportional valve, calculates a mean coefficient of friction of the first clutch assembly based on the sensed response of the first clutch assembly, and determines a remaining useful life of a portion of the wet clutch system based on the mean coefficient of friction of the first clutch assembly.

Abstract: A parallel, torque additive torsional compensating device for an internal combustion engine is provided. The torsional compensating device comprises a first gear in driving engagement with the output of the engine, a first Cardan joint assembly in driving engagement with the first gear, an intermediate shaft in driving engagement with the first joint assembly, a second joint assembly in driving engagement with the intermediate shaft, a clutching device in driving engagement with the second joint assembly, a torsional element oriented substantially parallel to the output of the engine in driving engagement with the clutching device, and a second gear in driving engagement with the torsional element and the output of the engine. An angular deviation of the first Cardan joint assembly causes a cyclical acceleration of the torsional element, applying a torque to the output of the internal combustion engine through the second gear and the second engagement portion.

Abstract: A variable transmission includes an input shaft, a planetary gear set drivingly engaged with a variator comprising, a variator carrier assembly, a first ring assembly, and a second ring assembly; and the output shaft, arranged with various combinations of brakes and clutches to produce transmissions with continuously variable or infinitely variable torque output ratios.

Abstract: A controller for a vehicle system and a method for updating a plurality of control settings and system parameters for a controller for a vehicle system are provided. The controller comprises a control unit portion, a prognostic module, a diagnostic module, and a telematics interface. The control unit portion is in communication with the vehicle system to initiate a vehicle system procedure. The prognostic module is in two way communication with the control unit portion. The diagnostic module is in communication with the prognostic module and is in two way communication with the control unit portion. The telematics interface is in two way communication with the control unit portion. A plurality of control settings and system parameters are sent to one of the diagnostic module and the prognostic module to be compared with previously stored data stored in one of the diagnostic module and the prognostic module.

Abstract: A torque vectoring device is provided. The torque vectoring device includes a drive member engaged with a power source, a plurality of spherical adjusters configured to be tiltable and rotatable with respect to the drive member, a first output frictionally engaged with the spherical adjusters, and a second output frictionally engaged with the spherical adjusters. A torque distribution between the first output and the second output may be adjusted by tilting the plurality of spherical adjusters. The spherical adjusters also facilitate a differential action between the first output and the second output.

Abstract: A method for estimating a total mass of a vehicle is provided. The method comprises the steps of providing a plurality of speed sensors configured to sense a rotational speed of a plurality of components of a driveline of the vehicle, estimating an output torque of the driveline of the vehicle, calculating gear losses based on the output torque of the driveline, estimating friction losses based on a rotational speed of a torque converter, calculating a rolling resistance of the vehicle, calculating an inertia of the vehicle, and estimating the total mass of the vehicle based on the inertia of the vehicle. The method uses currently available sensors found in a vehicle transmission to estimate a total mass of a vehicle or a vehicle payload.