In one aspect, a cab heating system for an electric work vehicle includes a hydraulic circuit forming a hydraulic flow loop through which a hydraulic fluid is directed for supply to a hydraulic component of the electric work vehicle. The system also includes a coolant circuit forming a coolant flow loop through which a coolant fluid is circulated, with the coolant circuit comprising a coolant heat exchanger. Additionally, the system includes a circuit heat exchanger thermally coupling the hydraulic circuit to the coolant circuit to allow heat to be transferred between the hydraulic fluid and the coolant fluid, and a fan configured to direct an airflow across the coolant heat exchanger such that heat is transferred from the coolant fluid to the airflow prior to delivery of the airflow into an interior of a cab of the electric work vehicle.

A thermal management system for an electric vehicle including an energy storage system and a vehicle component that requires cooling. A method for thermal management of an electric vehicle, and an electric vehicle including the thermal management system. The system including a heater arranged to heat the energy storage system, wherein the heater is arranged to be powered by either the energy storage system or an external power source, a control unit for controlling the heater and configured to identify when the heater is powered by the external power source, and to, when the heater is powered by the external power source receive data associated with the ambient temperature, determine whether the ambient temperature is below or above a minimum temperature, control the heater to heat the energy storage system when the ambient temperature is below the minimum temperature. The control unit is arranged to control the heater to heat the vehicle component when the heater is powered by the external power source and the ambient temperature is below the minimum temperature, and to direct excess heat from the vehicle component to the energy storage system when the heater is powered by the energy storage system.

A cooling system comprises a liquid storage tank and liquid disposed within the liquid storage tank. A first heat exchanger is immersed within the liquid, wherein refrigerant from an air conditioning system flows through the first heat exchanger. A second heat exchanger is also immersed within the liquid, wherein coolant from a load cooling system flows through the second heat exchanger.

Provided with a heat storage device having a simple and small shape without occupying large space when mounted on an electric car and capable of storing and releasing heat efficiently without using water so that the heat storage device is used as a heater. A heat storage device 10 includes: a heat storage material 14 configured to be oxidized and deoxidized by a temperature control operation; a heat transfer material 15 for heating the heat storage material 14; at least a pair of electrodes 11, 12 configured to be connected to a power source for heating the heat transfer material 15; a container 16 containing the heat storage material 14, the heat transfer material 15 and the at least a pair of electrodes; an upstream valve 17 provided on an upstream inlet of the container 16 for shielding an inside of the container 16 from an outside; and a downstream valve provided on a downstream outlet of the container 16 for shielding the inside of the container 16 from the outside.

The various embodiments described herein include methods, devices, and systems for conditioning air and heating water in a vehicle. In one aspect, a method includes: (1) obtaining a desired temperature for an interior of the vehicle; (2) obtaining a desired temperature for water in a water storage tank of the vehicle; (3) determining a current interior temperature; (4) and a current water temperature; (5) if the current water temperature is below the desired water temperature, and if the current interior temperature is below the desired interior temperature, operating a system in a first mode to concurrently heat the water and heat the interior; and (6) if the current water temperature is below the desired water temperature, and if the current interior temperature is above the desired interior temperature, operating the system in a second mode to concurrently heat the water and cool the interior.

The various embodiments described herein include methods, devices, and systems for conditioning air and heating water in a vehicle. In one aspect, a method includes: (1) obtaining a desired temperature for an interior of the vehicle; (2) obtaining a desired temperature for water in a water storage tank of the vehicle; (3) determining a current interior temperature; (4) and a current water temperature; (5) if the current water temperature is below the desired water temperature, and if the current interior temperature is below the desired interior temperature, operating a system in a first mode to concurrently heat the water and heat the interior; and (6) if the current water temperature is below the desired water temperature, and if the current interior temperature is above the desired interior temperature, operating the system in a second mode to concurrently heat the water and cool the interior.

The invention concerns an installation for the thermal conditioning of a passenger compartment and/or at least one component of a motor vehicle, comprising a first circuit (1) for circulating a heat transfer fluid, a second circuit (2) for circulating a refrigerant fluid, capable of forming a heat pump type circuit, the heat transfer fluid circuit comprising heating and/or cooling means (M1, M2, M3) for at least one component of a motor vehicle, means (S1, S2) for storing calories and/or frigories, a first exchanger (E1) forming an evaporator and capable of exchanging heat with the refrigerant circuit, and means for circulating the heat transfer fluid capable of drawing the frigories and/or calories from the storage means (S1, S2) or the first exchanger (E1), so as to transfer them to the heating and/or cooling means (M1, M2, M3).

Systems and methods are described herein for controlling heat flow between systems of an electric automotive vehicle. An automotive electric vehicle system includes a high voltage battery system including an enclosure, an electric powertrain system, a radiator, coolant lines that permit coolant flow between the high voltage battery system, the power train system and the radiator, one or more valves for routing coolant along the coolant lines, and a controller. The controller is configured to control the one or more valves to control the flow of coolant among a plurality of different, selectable coolant flow states involving the high voltage battery system, the powertrain system and the radiator.

Systems and methods are described herein for controlling heat flow between systems of an electric automotive vehicle. An automotive electric vehicle system includes a high voltage battery system including an enclosure, an electric powertrain system, a radiator, coolant lines that permit coolant flow between the high voltage battery system, the power train system and the radiator, one or more valves for routing coolant along the coolant lines, and a controller. The controller is configured to control the one or more valves to control the flow of coolant among a plurality of different, selectable coolant flow states involving the high voltage battery system, the powertrain system and the radiator.

The invention relates to a system that is added to a standard vehicle installed air-conditioning system that allows the standard vehicle installed air-conditioning system to cool and condition the air inside the vehicle without operating the engine of the vehicle. This allows the vehicle to be air-conditioned without polluting the air via continuous operation of the vehicle's (usually) diesel engine. Also, a thermal heating tank is included to warm the electrical components of the system and to ensure improved morning starting of the vehicle's engine. Also, an interiorly operating alternator recaptures some of the energy generated by the system when the air conditioning compressor is disconnected from the electric motor that powers it, but the electric motor remains activated.