An energy recovery system for a power system is disclosed. The power system includes an engine, a generator driven by the engine, an electrical bus configured to receive electrical power from the generator, an exhaust conduit configured to receive exhaust gases from the engine, and a turbocharger coupled to the exhaust conduit. The energy recovery system includes a bypass conduit, a turbo-generator, and a synchronizer. The bypass conduit is coupled to the exhaust conduit, and facilitates a portion of exhaust gases from the exhaust conduit to bypass the turbocharger. The turbo-generator is coupled to the bypass conduit, and is driven by the portion of exhaust gases bypassing the turbocharger. Further, the synchronizer modulates one or more parameters of electrical power received from the turbo-generator based on one or more parameters of electrical power present on the electrical bus. The synchronizer transmits modulated electrical power to the electrical bus.

Various embodiments for an exhaust gas treatment device for a vehicle system are provided. In one example, the vehicle system includes an engine with a longitudinal axis, where a crankshaft of the engine is parallel to the longitudinal axis and an exhaust gas treatment device mounted on the engine, vertically above the engine such that a longitudinal axis of the exhaust gas treatment device is aligned in parallel with the longitudinal axis of the engine, the exhaust gas treatment device configured to receive exhaust gas from an exhaust manifold of the engine.

Various embodiments for an exhaust gas treatment device for a vehicle system are provided. In one example, the vehicle system includes an engine with a longitudinal axis, where a crankshaft of the engine is parallel to the longitudinal axis and an exhaust gas treatment device mounted on the engine, vertically above the engine such that a longitudinal axis of the exhaust gas treatment device is aligned in parallel with the longitudinal axis of the engine, the exhaust gas treatment device configured to receive exhaust gas from an exhaust manifold of the engine.

A power system is disclosed. The power system may have a cryogenic tank configured to hold a supply of liquid fuel, and an engine configured to combust gaseous fuel. The power system may also have a coolant circuit configured to cool the engine, and at least one heat exchanger isolated from the coolant circuit and configured to receive a fluid passing through the engine. The power system may further have a first fuel line extending from the cryogenic tank to the at least one heat exchanger, and a second fuel line extending from the at least one heat exchanger to the engine.

A power system is disclosed. The power system may have a cryogenic tank configured to hold a supply of liquid fuel, and an engine configured to combust gaseous fuel. The power system may also have a coolant circuit configured to cool the engine, and at least one heat exchanger isolated from the coolant circuit and configured to receive a fluid passing through the engine. The power system may further have a first fuel line extending from the cryogenic tank to the at least one heat exchanger, and a second fuel line extending from the at least one heat exchanger to the engine.

A thermoelectric generator for converting heat of a hot gas flow into electric energy can include at least one thermoelectric module with a plurality of thermoelectric elements. A gas channel on a high-temperature side of the thermoelectric module can conduct the hot gas flow in a flow direction of the gas channel. A heat sink can cool the thermoelectric module and be in contact with the thermoelectric module on a low-temperature side thereof. At least one heat conducting body can extend into the gas channel in a direction running transversely to the flow direction on the high-temperature side of the thermoelectric module and can have a free end within the gas channel. The heat conducting body can be part of the thermoelectric module or connected thereto on the high-temperature side. The thermoelectric generator can have a seal which separates an area between the heat sink and the gas channel from the gas channel and seals the area from the hot gas flow.

A thermoelectric generator for converting heat of a hot gas flow into electric energy can include at least one thermoelectric module with a plurality of thermoelectric elements. A gas channel on a high-temperature side of the thermoelectric module can conduct the hot gas flow in a flow direction of the gas channel. A heat sink can cool the thermoelectric module and be in contact with the thermoelectric module on a low-temperature side thereof. At least one heat conducting body can extend into the gas channel in a direction running transversely to the flow direction on the high-temperature side of the thermoelectric module and can have a free end within the gas channel. The heat conducting body can be part of the thermoelectric module or connected thereto on the high-temperature side. The thermoelectric generator can have a seal which separates an area between the heat sink and the gas channel from the gas channel and seals the area from the hot gas flow.

Systems and methods for a cab-mounted muffler assembly are provided. In one embodiment, a system includes a support structure configured to couple to an engine cab within an interior of the engine cab; and a muffler assembly configured to mount to the support structure within the interior and spaced apart from an engine by the support structure. The muffler assembly is mounted to the support structure vertically above the engine relative to a ground surface on which the engine cab is supported.

Systems and methods for a cab-mounted muffler assembly are provided. In one embodiment, a system includes a support structure configured to couple to an engine cab within an interior of the engine cab; and a muffler assembly configured to mount to the support structure within the interior and spaced apart from an engine by the support structure. The muffler assembly is mounted to the support structure vertically above the engine relative to a ground surface on which the engine cab is supported.

A ride-through control system for operating locomotives in a train includes a geographic position sensor configured to generate a signal indicative of a geographic position of a locomotive of a train, and a controller configured to receive the signal indicative of the geographic position of a locomotive and compare the geographic position of the locomotive with one or more pre-determined geographical locations or regions previously identified as geo-fences. The controller may also be configured to receive one or more locomotive operational signals indicative of at least one of an operational parameter, a fault, and a maintenance request associated with the locomotive, determine whether the geographic position of the locomotive coincides with a geo-fence characterized by conditions that may affect the ability of the locomotive to meet a trip objective if the locomotive were to slow below a threshold speed within the geo-fence, and generate a ride-through control command signal to prevent the locomotive from slowing below the threshold speed within the geo-fence based on at least one of the one or more locomotive operational signals and a user permission level.