Abstract: A solar powered ventilation system for regulating the interior temperature of a motorized vehicle and a method of controlling the same is provided. The vehicle includes a battery pack in electrical communication with at least one motor assembly that is selectively operable to propel the vehicle. The solar powered ventilation system includes a solar panel in electrical communication with a fan and the battery pack. The method includes: determining if sufficient solar load is available; if so, determining the current vehicle power mode; determining if the current battery pack temperature is greater than a threshold battery pack temperature if the vehicle is in “off” or “accessories on” mode; and commanding the solar powered ventilation system to modify the interior temperature of the vehicle to thereby decrease the temperature of the battery pack if the current battery pack temperature is greater than the threshold battery pack temperature.

Abstract: An accessory load control system for a vehicle, includes an actuator control module, a period estimation module, and a load control module. The actuator control module operates an internal combustion engine of the vehicle in a high-efficiency (HE) mode. The period estimation module estimates a period between a current time and a future time when an actual load on a crankshaft of the engine will reach a maximum engine load associated with the HE mode. The load control module selectively decreases engine loads applied by vehicle accessories, respectively, based on the period.

Abstract: A battery pack cooling and body pressure relief system for a vehicle having a passenger cabin is disclosed. The system may include an intake air flow duct connected between the passenger cabin and the battery pack, and an air flow duct connected between the exhaust air outlet and the body pressure relief valve. The system may include a one-way cabin pressure relief vent connected to the air flow duct and configured to selectively allow for air flow into the air flow duct, and may include a duct pressure relief vent connected to the air flow duct and configured to selectively allow for air flow out of the air flow duct into the vehicle.

Abstract: A system and method for controlling air flow through a passenger cabin and battery pack of a vehicle having a battery module is disclosed. A HVAC controller communicates with a battery pack controller to assure that air flow from the passenger cabin through the battery pack, and either out to atmosphere or returned to the passenger cabin, is coordinated to obtain desirable passenger cabin heating/cooling and battery cooling.

Abstract: A seat temperature control system having a temperature controlled seat for use in a vehicle is disclosed. The temperature controlled seat may comprise a seat bottom, a seat back and an air conditioning system. The seat bottom includes a bottom heat exchanger fluid coil configured to direct a cooling fluid therethrough from a bottom inlet end to a bottom outlet end. The seat back includes a back heat exchanger fluid coil configured to direct the cooling fluid therethrough from a back inlet end to a back outlet end. The air conditioning system includes a coils inlet line in fluid communication with the bottom inlet end and the back inlet end, and a coils outlet line in fluid communication with the bottom outlet end and the back outlet end. The air conditioning system provides cooling fluid to the coils and receives cooling fluid from the coils.

Abstract: The method for thermal management of a battery can include vehicle systems to control the thermal input to the battery and a dedicated battery thermal management system. The battery thermal management system includes transferring battery heat to coolant flowing in a circuit, if ambient air temperature is greater than the battery temperature, using an evaporator/chiller to transfer heat from the coolant to a refrigerant, using a condenser to transfer heat from the refrigerant to the coolant, and using a radiator to transfer heat from the coolant to ambient air; and if coolant can be maintained in the reference temperature range without using a heat source or refrigerant, using a radiator to transfer heat from the coolant to the ambient air.

Abstract: An exhaust heat recovery heat exchanger assembly for use along a main exhaust flow path of an exhaust system for an engine, and a method of operation, is disclosed. The exhaust heat recovery heat exchanger includes a sealed vacuum chamber, including a hydride pellet mounted in the chamber, and electrical leads extending from the hydride pellet. An exhaust chamber along the main exhaust flow path is located along an inner wall of the vacuum chamber. A housing surrounds the vacuum chamber and defines a heat receiving medium chamber. A heat receiving medium flows through the heat receiving medium chamber and absorbs heat from the exhaust flowing through the exhaust chamber when an electric current is applied to the hydride pellet.

Abstract: A method of operating a HVAC system in a vehicle having an engine that operates in a high efficiency mode and a less efficient mode is disclosed. The method may comprise the steps of: operating a refrigerant compressor to cool a passenger compartment and charge a cold thermal storage apparatus; determining if a cold charge in the storage apparatus has exceeded a threshold; enabling compressor cycling if the cold charge in the storage apparatus has exceeded the threshold; detecting if the engine is operating in the high efficiency mode; determining an amount of HVAC loads on the engine; determining a proximity of the engine operation to a switching point from the high efficiency mode to the less efficient mode; and conducting a HVAC load shed if the HVAC load reduction allows the engine to stay below the switching point and the compressor cycling is enabled.

Abstract: An HVAC system for use in a vehicle. The HVAC system comprises an evaporator, a refrigerant compressor that receives a refrigerant from the evaporator and compresses the refrigerant, a condenser that receives the refrigerant from the compressor and has fins with air flowing through the fins to remove heat from a refrigerant flowing through the condenser, and an expansion device that receives the refrigerant from the condenser and directs the refrigerant to the evaporator. The HVAC system also comprises a water tank that receives and stores water, a water spray pump that receives water from the water tank, and a nozzle that receives water from the water spray pump and is located adjacent to the condenser, with the nozzle selectively spraying water on the fins of the condenser.

Abstract: A fluid-based or fluidic climate control system for a seat includes first and second portions positionable adjacent to first and second surfaces of the seat and a fluid control module (FCM) for circulating fluid in a closed-loop within the portions. The FCM delivers fluid to the portions at independently-controllable temperatures. An interface may be used to control the temperatures. The FCM may include a heat exchanger module (HEM) having a fan connected to an energy storage device (ESD). The FCM may include a miniature vapor compressor for circulating the fluid. A method of cooling a seat includes positioning first and second portions of the system adjacent to different surfaces of the seat, and using the FCM to circulate fluid within a closed-loop passage of the portions while independently controlling the temperature of the fluid, and thus the portions, using a user interface.

Abstract: A system for heating and cooling a vehicle includes a solar panel disposed on a surface of a vehicle and a thermoelectric unit i) disposed on or in an internal surface disposed in a cabin area of the vehicle, and ii) operatively connected to the solar panel. The thermoelectric unit is configured to heat and/or cool the internal surface in response to electric current applied thereto from the solar panel. The system further includes a control unit operatively associated with the thermoelectric unit. The control unit is configured to determine the amount and direction of the electric current to be applied to the thermoelectric unit based on i) a measured ambient temperature, ii) a measured temperature of the internal surface, and iii) a user-preferred reference temperature.

Abstract: Thermoelectric modules are disposed to be connected to a vehicle coolant system and to an air handling system to provide localized climate control and passenger compartment climate control. Vehicle coolant acts as a heat sink in cooling mode and a heat source in heating mode in embodiments. A system controller in embodiments is disposed to monitor an input for a signal that a monitored climate characteristic has departed from a predefined range of values.

Abstract: An HVAC system, and a method of operation, for use in a vehicle is disclosed. The HVAC system may comprise: an evaporator having a drain that receives condensate dripping from the evaporator; a refrigerant compressor that receives a refrigerant from the evaporator and compresses the refrigerant; a condenser that receives the refrigerant from the compressor; and a condensate-to-refrigerant heat exchanger that receives the refrigerant from the condenser and the condensate from the drain, whereby the condensate absorbs heat from the refrigerant as the condensate flows through the condensate-to-refrigerant heat exchanger.

Abstract: A method of controlling a power input to a compressor clutch, via an A/C clutch voltage controller, that selectively drives an A/C compressor in a vehicle HVAC system is disclosed. The method may comprise the steps of: determining a first electric power level needed to cause the compressor clutch to move to a full engagement position from a compressor clutch non-engagement position; applying the first electric power level to the compressor clutch to cause the compressor clutch to move to the full engagement position; determining a second electric power level, which is lower than the first electric power level, needed to maintain the compressor clutch in the full engagement position; and applying the second electric power level to the compressor clutch to maintain the compressor clutch in the full engagement position.

Abstract: A solar powered ventilation system for regulating the interior temperature of a motorized vehicle and a method of controlling the same is provided. The vehicle includes a battery pack in electrical communication with at least one motor assembly that is selectively operable to propel the vehicle. The solar powered ventilation system includes a solar panel in electrical communication with a fan and the battery pack. The method includes: determining if sufficient solar load is available; if so, determining the current vehicle power mode; determining if the current battery pack temperature is greater than a threshold battery pack temperature if the vehicle is in “off” or “accessories on” mode; and commanding the solar powered ventilation system to modify the interior temperature of the vehicle to thereby decrease the temperature of the battery pack if the current battery pack temperature is greater than the threshold battery pack temperature.

Abstract: An HVAC system for a vehicle is disclosed. The HVAC system may comprise an HVAC module configured to selectively direct conditioned air through an HVAC outlet; and an HVAC air distribution system including a duct operatively engaging the HVAC outlet to receive air flow therefrom, a top outlet configured to be positioned above an instrument panel, a heater outlet configured to be located below the instrument panel, and a diverter located in the duct and configured to selectively direct the air flow from the HVAC outlet through the duct to the top outlet and the heater outlet.

Abstract: A method and system for removing oil accumulation from refrigerant lines of a vehicle HVAC system having multiple refrigerant loops each having an evaporator is disclosed. The method for operating the system may comprise the steps of: monitoring a flow rate through at least one of the refrigerant loops; determining if the flow rate through any of the at least one refrigerant loops being monitored is below a predetermined flow rate for greater than a predetermined time limit; monitoring for an indication of imminent vehicle operation; and if the indication of imminent vehicle operation is detected and the flow rate through any of the at least one refrigerant loops being monitored is below the predetermined flow rate for greater than the predetermined time limit, opening a valve to allow for maximum flow through the at least one refrigerant loop.

Abstract: A vehicle-integrated water harvesting system is provided that enables water-vapor or condensation in a vehicle to be captured, and made available onboard the vehicle for drinking or other uses. The system includes a water emitting component and may include a purification system operatively connected to the water emitting component. The purification system at least partially purifies the water and then sends the purified water to a storage reservoir or directly to a dispenser or outlet.

Abstract: A method of operating a HVAC system in a vehicle having an engine that operates in a high efficiency mode and a less efficient mode is disclosed. The method may comprise the steps of: operating a refrigerant compressor to cool a passenger compartment and charge a cold thermal storage apparatus; determining if a cold charge in the storage apparatus has exceeded a threshold; enabling compressor cycling if the cold charge in the storage apparatus has exceeded the threshold; detecting if the engine is operating in the high efficiency mode; determining an amount of HVAC loads on the engine; determining a proximity of the engine operation to a switching point from the high efficiency mode to the less efficient mode; and conducting a HVAC load shed if the HVAC load reduction allows the engine to stay below the switching point and the compressor cycling is enabled.

Abstract: A system for reducing thermal energy in the interior of an unoccupied vehicle includes an energy source, a temperature sensor, and a control unit which triggers the system in response to satisfaction of conditions. The conditions include the temperature of the passenger compartment being greater than a target temperature and the vehicle engine not running. A fan configured to selectively bring ambient air into the passenger compartment is powerable by the energy source and circulates ambient air through the passenger compartment in response to the control unit. The energy source may include a solar panel or another source characterized by absence of energy derived from the vehicle engine, and excess energy may be distributed to an energy storage device. A seat ventilation fan may operate concurrently with the fan or an HVAC. A method of reducing thermal energy in the interior of a parked vehicle is also provided.