A cooperative control method for an energy conversion apparatus is disclosed. The cooperative control method includes: acquiring a target heating power, a target driving power, and a target charging and discharging power; acquiring a first heating power of a motor coil according to the target charging and discharging power; acquiring a second heating power of the motor coil according to the target driving power; adjusting a first quadrature axis current and a first direct axis current to a target quadrature axis current and a target direct axis current when a difference between a sum of the first heating power and the second heating power and the target heating power is not within a preset range, to cause the difference between the sum of the first heating power and the second heating power and the target heating power to be within the preset range; and acquiring a sampling current value on each phase coil and a motor rotor position, and calculating a duty cycle of each phase bridge arm in a reversible pulse width modulation (PWM) rectifier.

Systems and methods for charging a battery of an electric vehicle are provided. One method includes heating a battery of the electric vehicle using a battery charger of the electric vehicle. The method includes using the battery charger to generate heat without charging the battery with the battery charger, and transferring the heat generated using the battery charger to the battery to heat the battery. Once a temperature of the battery is sufficiently high to accept a charge, the battery charger may be used to charge the battery.

Systems and methods for charging a battery of an electric vehicle are provided. One method includes heating a battery of the electric vehicle using a battery charger of the electric vehicle. The method includes using the battery charger to generate heat without charging the battery with the battery charger, and transferring the heat generated using the battery charger to the battery to heat the battery. Once a temperature of the battery is sufficiently high to accept a charge, the battery charger may be used to charge the battery.

Operating a motor vehicle (1) by adjusting the temperature of one or more vehicle parts (3, 4). One method includes specifying (S2) an indication of an expected beginning-of-driving time (FBZ) of the motor vehicle (1) and a desired operating temperature (BT) of the one or more vehicle parts (3, 4); and waking up (S6) a controller (22), which is configured to control adjustment of the temperature of the respective vehicle part (3, 4), at a temperature-adjustment starting time (A2) which is chosen such that, if heating up or cooling down begins at the temperature-adjustment starting time (A2), the heating up or cooling down ends, by reaching the desired operating temperature (BT) of the corresponding vehicle part (3, 4), at a time which corresponds to the expected beginning-of-driving time (FBZ) or is just before the expected beginning-of-driving time (FBZ).

In a coolant circulation system of a vehicle, a connecting unit is connected to a coolant line of a vehicle circulating through a battery of the vehicle. When connected to the coolant line, the connecting unit allows coolant to be discharged from the vehicle or be introduced into the coolant line. A supply unit includes a cooling tank in which the coolant is stored or circulates and a heating tank. The cooling tank includes an evaporation core, and the heating tank includes a condensing core. The evaporation core and the condensing core are connected to the coolant line on which a compressor, an expansion valve, and an external condenser are provided. When the connecting unit is connected to the coolant line, the supply unit is configured to supply the coolant from the cooling tank or the heating tank to the coolant line of the vehicle, cooling or heating the battery.

A method for a battery system for a vehicle is provided. The battery system can include a plurality of battery modules and a heat transfer assembly. Each of the battery modules can include one or more cells. The battery modules are selectively electrically connectable to a terminal of the battery system in order to provide electrical power to the vehicle. The heat transfer assembly can selectively adjust thermal energy levels of one or more of the battery modules. The method can include determining a desired capacity of the battery system, determining a number of the battery modules to have thermal energy levels adjusted by the heat transfer assembly according to the desired capacity of the battery system, and operating the heat transfer assembly to adjust thermal energy levels of the determined number of battery modules.

A method for a battery system for a vehicle is provided. The battery system can include a plurality of battery modules and a heat transfer assembly. Each of the battery modules can include one or more cells. The battery modules are selectively electrically connectable to a terminal of the battery system in order to provide electrical power to the vehicle. The heat transfer assembly can selectively adjust thermal energy levels of one or more of the battery modules. The method can include determining a desired capacity of the battery system, determining a number of the battery modules to have thermal energy levels adjusted by the heat transfer assembly according to the desired capacity of the battery system, and operating the heat transfer assembly to adjust thermal energy levels of the determined number of battery modules.

An electrical energy store for the storage of electrical energy for a motor vehicle, includes a housing which delimits a receptacle space, storage cells which are arranged in the receptacle space for the storage of the electrical energy, and a line element, which accommodates a through-flow of a coolant fluid for cooling the energy store. The line element has at least one longitudinal region which is routed in the receptacle space and is constituted of a first material having a first melting temperature, and at least one outflow opening that terminates in the receptacle space. A closure element closes the outflow opening and is constituted of a second material, which differs from the first material and has a second melting temperature which is lower than the first melting temperature. The closure element is to be melted for the release of the outflow opening. The storage cells are constituted as solid-body accumulators.

A battery control system for a battery electric vehicle is configured to detect that a driver door of the vehicle has been opened and connect the battery system to an electrical system of the vehicle to power at least a cabin heater and defroster of the vehicle, detect a driver start request, determine whether a set of battery parameters satisfy a threshold indicative of the battery system being sufficiently conditioned for driving of the vehicle, and when the set of battery parameters satisfy the threshold, display, via the user interface, a first message indicating that the vehicle is ready to drive and allow the driver to drive the vehicle and driving is prevented.

An AC generation circuit includes a first capacitor having a first end connected to a positive electrode side of a power storage having an inductance component, a second capacitor having a first end connected to a negative electrode side of the power storage, a parallel switch unit configured to connect the first capacitor and the second capacitor to the power storage in parallel by connecting a second end of the first capacitor and the first end of the second capacitor and connecting the first end of the first capacitor and a second end of the second capacitor in accordance with a first control signal, a series switch unit configured to connect the first capacitor and the second capacitor to the power storage in series by connecting the second end of the first capacitor and the second end of the second capacitor in accordance with a second control signal, and an inductor connected between both terminals of the series switch unit.