Patent application number | Description | Published |
20100274394 | Climate Control Head With Fuel Economy Indicator - A climate control system having a control head including a display providing at least one comfort level indicator and a fuel economy indicator is provided. The comfort level indicator displays a plurality of comfort level settings corresponding to relative thermal comfort in all weather conditions. Each comfort level setting corresponds to a range of temperatures so that once a comfort range is obtained, the climate control system will be reluctant to consume additional energy, thereby maintaining or improving the current fuel economy state. The fuel economy indicator provides for direct communication of the impact of comfort level settings on fuel economy. | 10-28-2010 |
20100286830 | Climate Control System And Method For Optimizing Energy Consumption Of A Vehicle - A climate control system and method for optimizing energy consumption in a hybrid electric vehicle (HEV) is provided. By varying evaporator temperatures based on occupant settings and environmental conditions, electric compressor speed can be optimized to provide the necessary cooling capacities resulting in energy savings. Determining the impact that increasing or decreasing engine cooling fan speed has on the overall energy consumption of the climate control system without affecting target discharge air temperature provides for energy saving opportunities. Optimizing energy consumption according to the provided strategy provides for improved fuel economy without sacrificing passenger comfort. | 11-11-2010 |
20110082594 | Climate Control System And Method For Optimizing Energy Consumption of A Vehicle - A climate control system includes a control head having a warmer/cooler temperature control for providing relative thermal comfort. A thermal comfort rating (TCR) corresponding to a range of passenger cabin temperatures is determined based upon a comfort level selection by an occupant using the control head. A control strategy employs look-up tables corresponding to the TCR to determine the speed of an electric compressor and the position of a temperature control blend door. The strategy provides for a relatively fast ramp down to a minimum compressor speed to improve fuel economy while maintaining a relative level of thermal comfort. | 04-07-2011 |
20110166747 | System And Method For Controlling Temperature In An Automotive Vehicle - A system and method is provided for controlling temperature in an automotive vehicle having a driver-side area, a front passenger-side area, and a climate control system with at least one interface. The interface allows a user to select a driver-side temperature setting and a passenger-side temperature setting. The system includes a seat occupancy sensor and at least one computer-based controller. In operation, the seat occupancy sensor generates a sensor signal indicative of passenger seat occupancy in the passenger-side area of the vehicle. Based on the sensor signal, the controller controls the climate control system. When the passenger-side area is unoccupied, the climate control system distributes conditioned air according to the driver-side temperature setting to both the driver-side and passenger-side areas. | 07-07-2011 |
20120009859 | PARTIAL AIR INLET CONTROL STRATEGY FOR AIR CONDITIONING SYSTEM - A system and method of selecting air intake between 100% fresh air mode and 100% recirculated air mode for optimum heating/cooling performance, fuel economy and/or high voltage (HV) battery power consumption is disclosed. The system and method includes a partial recirculation control strategy in which the air inlet door is moved progressively to any position by taking into account cooling/heating loads and cabin fogging probability. As cooling/heating loads increase the air inlet door moves toward 100% recirculation mode. As fogging probability increases the air inlet door moves toward 100% fresh air mode. By selectively choosing a position between 100% recirculation and 100% fresh air, fuel economy and/or HV battery power consumption is optimized without compromising passenger comfort or causing fogging on interior glass surfaces. In cooling applications the compressor load is minimized and air conditioning performance is improved due to the reduced evaporator cooling load. The direct result of this improvement is increased fuel economy in the case of the internal combustion vehicle, reduced engine on time in the case of the hybrid electric vehicle (due to reduced HV battery power consumption), and reduced HV battery power consumption in the case of the hybrid electric vehicle (HEV) and the electric vehicle (EV). In heating applications, as the heating load is reduced the fuel economy of the internal combustion (IC) engine will be improved, the engine on time is reduced in the case of the HEV, and HV battery power consumption is reduced in the case of the EV. | 01-12-2012 |
20120067559 | SYSTEM AND METHOD FOR ENVIRONMENTAL MANAGEMENT OF A VEHICLE - A system and method for environmental management of a vehicle automatically operates a vehicle climate control system to quickly and efficiently defog a vehicle windshield, while still operating at or near environmental comfort guidelines determined by a vehicle occupant. The method may be executed by an HVAC control system that is configured with a preprogrammed algorithm to operate an HVAC to achieve the desired results. A number of sensors can provide inputs to the control system, which can also receive inputs from a number of manual overrides operable by an occupant of the vehicle. The preprogrammed algorithm is configured to act on the various inputs to operate the HVAC to strike an appropriate balance between occupant comfort and windshield defogging. | 03-22-2012 |
20120234930 | AUTOMATIC REMOTE START/STOP CONTROL STRATEGY FOR VEHICLE HEATING AND COOLING SYSTEMS - A system and method for preconditioning a vehicle interior via a remote start device based on then-current weather conditions independent of the previous climate control head settings in place at the termination of the vehicle's last use are disclosed. The preconditioning system and method may be used in either electronic automatic temperature control (EATC) systems or in manual temperature control (MTC) systems. When used in conjunction with an EATC system, variables including sunload, Tset point (that is, the temperature door position), Tambient, and Tcabin are used to calculate the climate load demand. When used in conjunction with an MTC system, Tambient, Tset point, and Tcabin are used to calculate the climate load demand. In the event that the MTC system does not have a Tcabin sensor then Tevaporator thermister is used to calculate the climate load demand in the beginning of the remote start. The disclosed system and method also has windshield defrosting/defog and rear glass defrost capabilities. The disclosed control strategies are also capable of turning on/off the heated/cooled seats (when present) and the heated steering wheel (when present) according to the cabin thermal comfort conditions. | 09-20-2012 |
20120239251 | CLIMATE CONTROL SYSTEM AND METHOD FOR OPTIMIZING ENERGY CONSUMPTION OF A VEHICLE - A climate control system and method for optimizing energy consumption in a hybrid electric vehicle (HEV) is provided. By varying evaporator temperatures based on occupant settings and environmental conditions, electric compressor speed can be optimized to provide the necessary cooling capacities resulting in energy savings. Determining the impact that increasing or decreasing engine cooling fan speed has on the overall energy consumption of the climate control system without affecting target discharge air temperature provides for energy saving opportunities. Optimizing energy consumption according to the provided strategy provides for improved fuel economy without sacrificing passenger comfort. | 09-20-2012 |