This patent application is directed to thermal management systems of vehicles with an electric powertrain. More specifically, the battery system and one or more powertrain components and/or cabin climate control components of a vehicle share the same thermal circuit as the battery module through which heat can be exchanged between the battery module and one or more powertrain or climate control components as needed.

An interlock system used in a high voltage system including a high voltage power supply in which a first voltage is a specified voltage and a plurality of high voltage system loads each connected to the high voltage power supply via a power supply line, the interlock system including: an acquisition unit that acquires information of a voltage applied to an own load from each of the high voltage system loads; and a control unit that controls a voltage of the power supply line, in which before activating the high voltage system, the control unit causes a second voltage lower than the first voltage to be output to the power supply line, and after the second voltage is output, when the acquisition unit has not acquired information that the second voltage is applied from all high voltage system loads, the control unit cancels activation of the high voltage system.

A working machine includes one or more batteries driving movement of the working machine within a work area. The working machine includes a controller configured to receive criteria relating to one or more operational characteristics of the working machine and determine one of a plurality of operation modes for the working machine based upon the criteria and a remaining charge of one or more batteries.

A working machine includes one or more batteries driving movement of the working machine within a work area. The working machine includes a controller configured to receive criteria relating to one or more operational characteristics of the working machine and determine one of a plurality of operation modes for the working machine based upon the criteria and a remaining charge of one or more batteries.

A switching arrangement for a motor vehicle powered at least partially electrically, including at least one inverter for converting a DC voltage of a high-voltage battery into a multi-phase AC voltage for a travel drive, at least one intermediate circuit capacitor connected to the inverter, and at least one pre-charge resistor, wherein, in a pre-charge mode, the pre-charge resistor serves to prevent current spikes during charging of the at least one intermediate circuit capacitor and, in a heating mode, serves for heating a coolant, wherein electrical current flows through the inverter in both the pre-charge mode as well as in the heating mode.

An EHC is configured to electrically heat a catalyst that purifies exhaust gas from an exhaust path of an internal combustion engine mounted on an electrically-powered vehicle, when a current passes through the EHC. A charger converts AC electric power supplied from an external power supply to a charging port into charging power of a power storage device by a power conversion path including an insulating transformer. The EHC is electrically connected to power lines which are provided on the primary side of the insulating transformer on the power conversion path, and to which a DC voltage is output. In a case where the EHC is operated when the vehicle travels, the charger converts the electric power from the power storage device into the DC voltage output to the power lines connected to the EHC, by a part of inverse conversion of power conversion at the time of external charging.

An EHC is configured to electrically heat a catalyst that purifies exhaust gas from an exhaust path of an internal combustion engine mounted on an electrically-powered vehicle, when a current passes through the EHC. A charger converts AC electric power supplied from an external power supply to a charging port into charging power of a power storage device by a power conversion path including an insulating transformer. The EHC is electrically connected to power lines which are provided on the primary side of the insulating transformer on the power conversion path, and to which a DC voltage is output. In a case where the EHC is operated when the vehicle travels, the charger converts the electric power from the power storage device into the DC voltage output to the power lines connected to the EHC, by a part of inverse conversion of power conversion at the time of external charging.

The invention relates to a fuel cell vehicle (200), in which the driver has more influence on the consumption and the dynamic of the vehicle (200). This is achieved by the fuel cell vehicle (200) comprising at least one sensor for detecting a first driver input and a control unit (60). The control unit (60) is configured to operate the fuel cell vehicle (200) in one of a plurality of operating modes depending on the first driver input, wherein a power consumption P.sub.AC of the air-conditioning system (70), an operating range of the fuel cell stack (10), and a transfer function for determining the power demand P.sub.EM from the second driver input are varied depending on the selected operating mode. It is provided that the driver has at least five different operating modes available, which differ in particular with respect to the available driving dynamic, the fuel consumption, and the adjustable comfort.

The invention relates to a fuel cell vehicle (200), in which the driver has more influence on the consumption and the dynamic of the vehicle (200). This is achieved by the fuel cell vehicle (200) comprising at least one sensor for detecting a first driver input and a control unit (60). The control unit (60) is configured to operate the fuel cell vehicle (200) in one of a plurality of operating modes depending on the first driver input, wherein a power consumption P.sub.AC of the air-conditioning system (70), an operating range of the fuel cell stack (10), and a transfer function for determining the power demand P.sub.EM from the second driver input are varied depending on the selected operating mode. It is provided that the driver has at least five different operating modes available, which differ in particular with respect to the available driving dynamic, the fuel consumption, and the adjustable comfort.

A vehicle power supply control device includes a plurality of area power supply slaves connected with respective different device groups configured with a plurality of different devices installed in a vehicle, and controlling power supplied to the devices in the connected device groups, a plurality of area power supply masters that are connected with respective different area power supply slaves and control power supplied to the connected area power supply slaves, and a vehicle power supply master connected with the area power supply masters and a battery of the vehicle and controlling power supplied to the area power supply masters from the battery.