Abstract: A system for controlling the climate in a cabin space using the state of a user's hand is provided. The system includes a controller and a heating ventilation and air conditioning system (HVAC system). The HVAC system is operable to direct air into the cabin space so as to maintain a predetermined climate within the cabin space. The controller is operable to actuate and control the HVCAC system. The system further includes a handheld sensor operable to detect the state of the user's hand. The handheld sensor is in communication with the controller and transmits the state of the hand to the controller. The controller processes the state of the hand so as to calculate an HVAC system operating setting operable to optimize the user's comfort. The controller then actuates the HVAC system so as to execute the calculated heating ventilation and air conditioning system operating setting.

Abstract: A method of constant airflow control for a ventilation system is disclosed. The method includes various controls to accomplish a substantially constant airflow rate over a significant change of the static pressure in a ventilation duct. One control is a constant I·RPM control, which is primarily used in a low static pressure range. Another control is a constant RPM control, which is primarily used in a high static pressure range. These controls requires neither a static pressure sensor nor an airflow rate sensor to accomplish substantially constant airflow rate while static pressure changes. This is because these controls use only intrinsic control variables which are electric current and rotational speed of the motor. Also, the method improves the accuracy of the control by correcting certain deviations that are caused by the motor's current-RPM characteristics. To compensate the deviation, the method adopts a test operation in a minimum static pressure condition.

Abstract: The vehicular temperature control device includes an external housing, a pair of internal compartments and a mechanism in each compartment that allows the device to either cool off or warm up an interior area within a vehicle. One of the internal compartments includes a belt, a rotating fan attached to the belt, and a volume of water for evaporative cooling. This chamber will help cool down surrounding air. The other internal compartment also includes a belt and a rotating fan attached to the belt and, furthermore, a heating coil. This second compartment is designed to assist an individual in heating up the surrounding air.

Abstract: New ecological operating mode that limits ventilation and air conditioning in the cabin (3) of the aircraft when the ecological operating mode has been selected, the aircraft is stationed on the ground, the engines are off, the engines' start up system has not been activated, the pneumatic or electrical energy supply system that typically controls ventilation and air conditioning in the aircraft has been activated and is supplying air, to provide a new method of operating at an established minimum limit independent of the difference between the selected temperature and the temperature measured, saving energy, and reducing pollutant emissions and noise.

Abstract: When there arises a need to change an air conditioner capability, a vehicular air conditioner capable of easily meeting this need is achieved. Also, even if some of a plurality of air conditioner units break down, a vehicular air conditioner capable of properly air conditioning a vehicular space using other air conditioner units, is achieved. This vehicular air conditioner includes a controller 20 for calculating a total heat supply amount, based on a target temperature and an actual room temperature; at least one heater 5 and/or at least one cooler 6; a controller 20 that sets generated heat amounts of the heater 5 and/or the cooler 6 of each of the air conditioner units 30, based on a calculated total heat supply amount and the number of used air conditioner units 30; and a drive controller that controls operations of the heater 5 and/or the cooler 6, based on the generated heat amounts that have been set.

Abstract: A joint for a refrigerant adduction circuit defines a seat adapted to house an o-ring and comprises a first annular projection defining a first inclined surface tapered towards the seat, a second annular projection defining a second inclined surface tapered towards the seat, in which the first annular projection is axially between the seat and the second annular projection.

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 door actuating device for an air conditioner of a vehicle can efficiently prevent separation of a link member after the link member is coupled to a rotating member when operating two doors simultaneously by using one door actuator, and the rotating member has a simple structure, thereby increasing facility of fabrication and reducing the fabricating cost.

Abstract: An aircraft cooling system includes a refrigerant cycle including a first heat exchanger, a second heat exchanger, and a compressor. A component of the aircraft is in thermal communication with the first heat exchanger. A heat sink fluid passes through the second heat exchanger to absorb heat from the refrigerant cycle. A hydraulic motor is mechanically connected with the compressor and powered by the heat sink fluid, which is circulated by a pump.

Abstract: An internal cooling apparatus for automobiles includes a first expansion valve for spraying a coolant to a main evaporator through a high-pressure pipe, a compressor receiving the coolant evaporated in the main evaporator through a low-pressure pipe, a condenser receiving the coolant compressed in the compressor, and a plurality of sub-evaporators each being installed inside of a seat to contact an automobile passenger. One end of each of the sub-evaporators is communicated with the high-pressure pipe and the other end thereof is communicated with the low-pressure pipe such that part of the coolant sprayed through the first expansion valve is supplied to the compressor via each of the sub-evaporators.

Abstract: A vehicle dryer includes an energy-conserving rotatable inlet butterfly valve to selectively admit or block air to a fan encased in a blower housing. The valve includes a plate mounted on a shaft that extends across the inlet portion of the blower housing. The plate is rotated by its shaft to either an opened position for admitting air into a blower housing, or a closed position for blocking air from entering into the blower housing. A crank arm is coupled to the valve shaft, and a pneumatic cylinder includes a piston rod for turning the crank arm through a ninety-degree angle, thereby rotating the valve plate between its opened and closed positions.

Abstract: An air conditioner for vehicles in which the probability of executing pre-air conditioning is increased so that it may be prevented that the inside of the vehicle cannot be often in a comfortable state before the driver gets into the vehicle. The air conditioner performs air conditioning of a vehicle having a traveling motor and an engine as drive sources and comprises a pre-air conditioning main switch. The crew permits operation of pre-air conditioning by turning the switch on. When the pre-air conditioning main switch is set on, an engine control section performs charge preference control where battery charge takes precedence of engine fuel consumption and performs normal control where engine fuel consumption takes precedence when the pre-air conditioning main switch is set off.

Abstract: In an air-conditioning system for a vehicle, which has multiple heat sources (an evaporator and a heat accumulator), either one of the heat sources, for which the input energy amount for the unit cooling capacity is smaller than that for the other heat source, is preferentially used for performing the cooling operation, an energy amount for the air-conditioning operation can be reduced.

Abstract: An air-conditioning system allows adjustment of the vented air temperature of a rear seat evaporator. An electronic control system judges whether the surface of the rear seat evaporator is frosting up when 1) a target blowing rate of the rear seat blower is lower than a predetermined value, 2) a detected temperature of evaporator vented air is lower than a specified temperature TEa, and 3) a detected temperature of the outside air is lower than a specified temperature TAMa. A target temperature TEO is raised at this time, so that an electric motor of an electric compressor is stopped and refrigerant no longer flows into the rear seat evaporator. The surface temperature of the rear seat evaporator rises so that the rear seat evaporator can be defrosted.

Abstract: A vehicle HVAC system comprises an evaporator, a heater core, a variable airflow control device, and a baffle positioned downstream of the evaporator. The baffle has a geometrical configuration, e.g., apertures sufficient to prevent the formation of vortex like airflow patterns near the downstream side of the baffle when the HVAC system is in use.

Abstract: An evaporator includes a plurality of flat heat exchange tubes arranged in a left-right direction at a spacing with the widthwise direction thereof pointing forward or rearward, and fins arranged between respective adjacent pairs of heat exchange tubes. The fins have at least front edges thereof projected forwardly outward beyond the heat exchange tubes. Assuming that the amount of projection of the fins beyond the heat exchange tubes is X mm and that the heat exchange tubes are Y mm in thickness in the left-right direction, i.e., in height, X and Y have the relationship of 0.11Y?X?1.0Y. The surfaces of the fins can be drained of condensation water efficiently.

Abstract: An auxiliary air conditioning system (7) for a motor vehicle (1), comprising a first heat exchanger (17) adapted to be installed inside a passenger compartment (4) of the motor vehicle and an external unit (43) comprising an auxiliary engine (8), an auxiliary compressor (12) driven by the auxiliary engine (8) and a second exchanger (17). The system comprises a switching valve (20) for selectively setting a first refrigerating cycle operating mode in which the first heat exchanger (17) serves as an evaporator and the second heat exchanger (14) serves as a condenser, and a second heat pump operating mode, in which the first heat exchanger (17) serves as a condenser and the fluid of the second heat exchanger (14) is cut off and the operative fluid is allowed to flow through a heating device (30) to receive thermal power independently from the outside environment temperature.

Abstract: A cooling system for an aircraft has a refrigerant system to cool a second fluid for a use associated with an aircraft. A valve is operable to route the second fluid to be cooled by the refrigerant under a first set of conditions, and to route the second fluid to be cooled by ambient air from outside of the aircraft under a second set of conditions.

Abstract: A vehicle air conditioning system includes a compressor, a condenser, an evaporator, a humidity sensor and a controller. The compressor is configured to compress refrigerant and the condenser is fluidly coupled to the compressor to receive the refrigerant from the compressor. The evaporator is fluidly coupled to the condenser to receive the refrigerant from the condenser and fluidly coupled to the compressor to supply the refrigerant to the compressor. The humidity sensor is positioned proximate the evaporator to detect moisture density of air passing through the evaporator towards a vehicle passenger compartment. The controller is operatively coupled to the humidity sensor and the compressor to cycle the compressor on and off to maintain the moisture density in the air being cooled by the evaporator and sensed by the humidity sensor below a predetermined moisture density threshold.

Abstract: The present invention relates to a method for controlling a vehicle air-conditioner, which can prevent undershoot of an evaporator by performing a maximum capacity control or controlling an discharge capacity of a compressor through the outputting of an discharge capacity control value of the compressor directly before the stop of the air conditioner, and can improve the pleasant feelings of the passengers by preventing delay of response, which converges into the target temperature of the evaporator due to the delay of the decrease of the temperature of the evaporator.

Abstract: A cableless control system for an automobile air conditioner includes a slide pot potentiometer assembly for connection to an actuator arm on the back of a dashboard mounted control assembly. The position of the slide pot potentiometer assembly creates an electrical resistance signal which governs the position of the devices which moves the variable mechanical portions of the automobile air conditioner. The shape of the linear slide pot potentiometer assembly allows for the use of existing hardware and eliminates the need to run sheathed cables from the dashboard mounted control panel assembly to the mechanically variable portions which govern the operation of the automobile air conditioner.

Abstract: In an evaporator constituting part of a vehicular air conditioning apparatus, a first cooling section that faces a first front passage, and a second cooling section that faces a first rear passage are provided. At a boundary portion between the first cooling section and the second cooling section, a partition member constituted by a filled and hardened packing agent is formed. The partition member is formed so as to fill spaces, which are located between first fins that constitute the first cooling section and second fins that constitute the second cooling section. Air that flows through the first cooling section and air that flows through the second cooling section do not mix together in the interior of the evaporator by the partition member.

Abstract: In an air conditioner constructed to pass an air introduced into an air conditioning unit through an evaporator and a heater core both arranged in the unit, cooler pipes for the evaporator and heater pipes for the heater core are arranged to extend from the same side wall of the air conditioning unit.

Abstract: An aircraft system for improved cooling efficiency comprises at least one air conditioning pack, coupled to an aircraft, having at least one air compression device powered by at least one power source and having an air compression device inlet. The system further comprises at least one air flow path for redirecting a first portion of a first volume of aircraft interior outflow air from an aircraft interior to the air compression device inlet. The air flow path includes a shutoff valve to enable the air flow path during ground operation of the aircraft and to disable the air flow path for flight operation of the aircraft. The air compression inlet mixes the first volume of aircraft interior outflow air with a second volume of aircraft exterior inflow air to form an air mixture. The air conditioning pack conditions and circulates the air mixture into the aircraft interior.

Abstract: The present invention relates to a cooling and heating cabinet device of a rear seat side for a vehicle using a thermoelectric module that is mounted between rear seats of a vehicle, having cooling and heating functions and further having an arm-resting function irrespective of its activation as the cooling and heating device, and that makes the exhaust fan activated by the control of the controller of the air conditioning system, thereby achieving the air-refreshing function as well as the cooling or heating mode function of the cooling and heating cabinet.

Abstract: In an air conditioner for a vehicle, a blower of a blower unit includes a double-axial motor having a rotation axis positioned approximately in a vehicle top-bottom direction, a pair of centrifugal fans located at two sides of the double-axial motor in an axial direction, and a pair of scroll casings in which the centrifugal fans are accommodated, respectively. The two air outlet portions are arranged in the vehicle top-bottom direction, and are adjacent to be joined to an air inlet portion of the air conditioning unit, substantially as a single air outlet. Furthermore, the two air outlet portions are located approximately at the same height position as that of the air passing portion of the cooling heat exchanger, and have a height dimension (H2) at its downstream end side that is approximately equal to a height dimension (H1) of the air passing portion of the cooling heat exchanger.

Abstract: Described herein is a system for controlling an air-conditioning system within an environment, in particular the passenger compartment of a vehicle, said system comprising a plurality of sensors designed to detect quantities representing the thermal comfort of the occupants and an electronic control unit (ECU), which calculates, on the basis of said quantities, a temperature indicating the thermal comfort of the occupants of the environment, on the basis of which the actuator devices of the air-conditioning system are driven.

Abstract: Method for controlling a HVAC system in a vehicular compartment includes monitoring temperature of an occupant in the compartment from a location apart from the occupant, and controlling the HVAC system based on the monitored temperature. Occupant temperature may be monitored by infrared sensors, each arranged in an orientation to receive electromagnetic radiation from one or more seating locations in which occupants are likely to be situated. The temperature in each seating location is independently monitored. The HVAC system is controllable for each seating location based on the monitored temperature in that area. When monitoring of temperature in an area in which a driver of the vehicle is likely to be situated indicates presence of the driver, and no other areas indicate presence of a human occupant, the HVAC system is controllable such that all heat or air-conditioning provided by the HVAC system is directed to the driver.

Abstract: A work vehicle comprises a plurality of wheels; a vehicle body supported by the plurality of wheels and having a cabin, a front half region and a rear half region; an engine located in the rear half region of the vehicle body; and an air conditioning unit located in a lower forward region of the cabin and having an evaporator and a fan.

Abstract: An air conditioning system for a passenger transit vehicle includes a rooftop mounted air conditioning module that has a low profile airflow management arrangement on the passenger compartment side of the roof of the vehicle for discharging air from and returning air to the evaporator section on the exterior side of the rooftop of the vehicle.

Abstract: A humidity detecting apparatus includes a humidity sensor for detecting a relative humidity of air on an inner side of a window glass, an air temperature sensor for detecting a temperature of the air, a glass temperature sensor for detecting a temperature of the window glass, and a glass surface relative humidity calculation unit for calculating a glass surface relative humidity based on output values of the humidity sensor, the air temperature sensor and the glass temperature sensor. A heat conductive member is disposed between the glass temperature sensor and the window glass.

Abstract: An electric vehicle includes a frame having a cab; a plurality of hub wheel motors mounted to the frame, each hub wheel motor rotating a wheel; and an air conditioner mounted on the frame and thermally coupled to the cab, wherein the air conditioner includes an inverter driving an electric compressor and the inverter is coupled to an independent battery for air conditioning.

Abstract: A thermal storage and transfer system includes a cooling system and method using ice or other frozen material with heat pipes to produce a cool airstream. Preferably, the ice is disposed in a container with the condensers and evaporators of the heat pipes respectively inside and outside the container. A fan blows air across the evaporator sections through a duct to circulate within an enclosed airspace to be cooled. A separate refrigeration system which may be used to independently cool the airspace also freezes water or another liquid to produce the ice or other frozen material in the container. The cooling system is broadly applicable, including use on motor vehicles to provide cooling for several hours when the vehicle engine is off. A heating system includes an adsorbent heat exchanger for extracting heat from exhaust gases of an engine and heating an enclosed airspace.

Abstract: Noise occurring in an upright air-conditioning unit is greatly reduced. An upright air-conditioning unit 1 is disposed under a steering member support part 23, a vent opening 15 and a vent outlet port 20 are made to communicate with each other via a vent duct 25, a defrost opening 16 and a defrost outlet port 21 are made to communicate with each other via a defrost duct 26. The vent opening 15 assumes a position further frontward than the steering member support part 23 along the frontward/rearward direction relative to the vehicle body whereas the defrost opening 16 assumes a position further rearward than the steering member support part 23 along the frontward/rearward direction relative to the vehicle body.

Abstract: A vehicle heating, ventilation and air conditioning (“HVAC”) system includes an HVAC control, a fan, an evaporator downstream from the fan, a cooler box downstream from the evaporator, a condenser in fluid communication with the evaporator and a compressor in fluid communication with the condenser and the evaporator. A method for cooling items using the HVAC system includes detecting a cooler box signal from the HVAC control, in response to detecting the cooler box signal, opening or closing a valve interposed between the evaporator and the cooler box, and in response to detecting the cooler box signal, performing at least one of the following: changing an HVAC mode or adjusting power delivered to the fan. Opening the valve can allow cool air to travel through a passage toward the cooler box. Closing the valve can block cool air from traveling through the passage toward the cooler box.

Abstract: A control methodology for dynamically adjusting the switching limits of a cycled refrigerant compressor in an air conditioning system with the objective of achieving an optimal or specified tradeoff between compressor cycling frequency and discharge air temperature variation under all operating conditions. In a first embodiment, the compressor cycling limits are controlled to maintain a virtually constant discharge air temperature variation for all operating conditions. In a second embodiment, the compressor cycling limits are controlled so that the discharge air temperature variation changes in relation to the discharge air temperature to provide a virtually constant human comfort level for the occupants. And in a third embodiment, the compressor cycling limits are controlled so that the discharge air temperature variation changes in relation to the ambient or outside air temperature to provide a virtually constant human comfort level for the occupants.

Abstract: A vehicle heating, ventilation, and air conditioning system includes front and rear HVAC systems. A controller receives data from front and rear control panels and controls the front and rear HVAC systems. Actuating a rear manual button on the front control panel allows control of the rear HVAC system via the rear control. Engine coolant temperature is used to judge if the vehicle has been inoperative for a long time. If the vehicle has not been inoperative for long, and the rear manual button was actuated prior to the vehicle shut down, rear manual control over the rear HVAC system is enabled. If the vehicle has been inoperative for a long time, or if the rear manual button was not actuated immediately prior to vehicle shut down, rear manual control is not enabled, thereby preventing operation of the rear HVAC system by the rear control panel.

Abstract: A cabin for a work vehicle comprises: a driver's seat positioned within the cabin; cabin frames including at least a transverse frame located in a rear region of the cabin; a roof supported by at least some of the cabin frames; at least one air-conditioning duct located within the roof an air conditioning unit located rearwardly with respect to a rearward end of a seat portion of the driver's seat and adjacent the transverse frame for conditioning air and for feeding air-conditioned air into the at least one air-conditioning duct.

Abstract: A vehicle rear air conditioner includes an air conditioning case connected with a blower and having a face vent, a floor vent and a vent door for controlling opening and closing of the vents. An evaporator and a heater core are embedded in the air conditioning case and a temperature control door controls opening and closing of a cold and a hot air passageway. The rear air conditioner includes a passageway member in order to discharge part of air flowing through the cold air passageway or the hot air passageway toward one of the vents. The passageway member has an inlet for inducing the part of air and an outlet for discharging the part of air and the vent door includes at least one interference preventing part.

Abstract: A method for determining the desired ventilation air temperature of an automatic heating and air-conditioning system of a vehicle having an opening top is described. The open or closed state of the top of the vehicle is detected, and the heating and air-conditioning system is controlled and/or regulated in a number of different ways as a function of the state of the top. In the open state of the top, the desired ventilation air temperature is determined as a function of the speed of the vehicle. Also, in the open state of the top the desired ventilation air temperature is determined in such a manner that the top-closed desired ventilation air temperature is increased by a speed-dependent offset value.

Abstract: A cooling system for a vehicle comprises a compressor for compressing refrigerant, the compressor being adapted to be driven by a power source installed in the vehicle, a condenser for receiving compressed refrigerant from the compressor, an expansion device for expanding refrigerant from the condenser, and a liquid-to-liquid heat exchanger for receiving refrigerant from the expansion device and exchanging heat between the refrigerant and a liquid. The liquid may comprise a coolant, and a pump may be provided for pumping the coolant through the heat exchanger to a point of use such as a cooling garment to cool personnel on board the vehicle. Alternatively, the liquid may be a drinkable liquid which is pumped through the heat exchanger to a suitable dispensing system to provide an on-board supply of cool drinking liquid.

Abstract: The present invention provides a system for controlling the climate of a hybrid vehicle. The system includes a thermoelectric module, a heat exchanger, a pump, and a valve. The thermoelectric module includes thermoelectric elements powered by electric energy. The thermoelectric elements emit or absorb heat energy based on the polarity of the electrical energy provided. A tube containing coolant runs proximate the thermoelectric elements. To aid in the transfer of heat energy, a blower is provided to generate an air flow across the thermoelectric elements and the tube. The coolant is provided from the thermoelectric module to a heat exchanger that heats or cools the air flow provided to the cabin of the vehicle. The pump and valve are in fluid communication with the heat exchanger and thermoelectric module. The pump pressurizes the coolant flow through the tube and coolant lines. In a cooling mode, the valve is configured to selectively bypass the engine coolant system of the vehicle.

Abstract: A vehicular air-conditioning system provided with a vapor compression type refrigerating machine improved in practicality, provided with a vapor compression type refrigeration cycle 10 having a compressor 11 compressing and discharging a refrigerant and an outside heat exchanger 16 exchanging heat with the air outside of the cabin and the refrigerant and designed to be able to switch between a cooler cycle cooling vented air blown into the cabin and a heat pump cycle heating the vented air, a heating means 36 for using cooling water of an internal combustion engine EG as a heat source for heating the vented air, a vent mode switch 60c setting a defogging mode blowing out vented air toward the vehicle window glass by operation by a passenger, and a control means 50 controlling switching between the cooler cycle and heat pump cycle, the control means 50 selecting the cooler cycle and outputting a signal requesting operation to the internal combustion engine EG when the vent mode switch 60c is used to set the de

Abstract: An electric traction vehicle having: at least one pair of driving wheels; at least one reversible electric machine which can be mechanically connected to the driving wheels; an electronic power converter which pilots the electric machine; a storage system, which is aimed at storing electric energy, is connected to the electronic power converter and comprises at least one storage device; a passenger compartment; an air conditioning system of the passenger compartment which fulfills the function of regulating the temperature inside the passenger compartment; and a cooling system, which is completely independent and separate from the air conditioning system of the passenger compartment and uses a compression refrigeration cycle to cool at least one of the electric components, i.e. the electric machine, the electronic power converter and the storage system.

Abstract: An air conditioning system for an automobile prevents leakage of condensed water by locating two drain parts respectively on an air conditioning case and a protective cover having a drain structure beneath the air conditioning case. A drain hose, connected to and communicating with the drain parts, discharges the condensed water to the outside of the automobile without dispersion of the condensed water by forming a condensed water discharge pipe positioned on the protective cover. The protective cover, mounted on the bottom surface of the air conditioning case, surrounds the inflow and outflow pipes and has an auxiliary drain part formed at a side thereof. The drain hose connects the drain part of the air conditioning case with the auxiliary drain part of the protective cover.

Abstract: The invention can securely carry out an operation by a reduced number of the parts. The invention is provided with a base member having a gear lever arranged portion and a pinion member arranged portion, and provided with a communication hole communicating with the gear lever arranged portion in a closed wall portion of the pinion member arranged portion, a gear lever rotatably arranged in a bearing portion, having a gear portion and driving an output member (a control wire) based on a rotation, a pinion member rotatably arranged in the pinion member arranged portion and having a pinion portion engaging with the gear portion via the communication hole, a holder having a retention portion retaining the pinion member in one end, and having a fixing portion fixing to the base member in the other end, and an operation knob arranged so as to be outside fitted to the pinion member and integrally rotating the pinion member.

Abstract: An air conditioning system including an evaporator having a manifold and a plurality of tubes extending downward in a vertical direction from the manifold. The evaporator defines at least one PCM tank engaging the manifold for storing a phase change material. When operating in a first operating mode, heat is transferred from the phase change material to the refrigerant to freeze and cool the phase change material. When operating in a second operating mode, heat is transferred from the refrigerant to the frozen phase change material to condense the refrigerant. The condensed refrigerant falls downwardly through the tubes and receives heat from a flow of air to cool the air and evaporate the refrigerant. The evaporated refrigerant rises upwardly back to the low pressure of the cold manifold.

Abstract: In a vehicle air conditioner, when a passenger set temperature of a vehicle compartment is changed through an operation portion by a passenger, a storage portion updates a value of a control set temperature corresponding to a predetermined point of a detection area at a time of the changing operation to a value of the changed passenger set temperature, and stores therein the value of the updated temperature. Furthermore, when the detection point is not any one of the predetermined points, a control portion interpolates and calculates a control set temperature corresponding to the detection point from the control set temperature stored in the predetermined point of the detection area and the control set temperature stored in the predetermined point of a surrounding area around the detection area, and then controls the air-conditioning state in the vehicle compartment based on the interpolated and calculated control set temperature.

Abstract: An air conditioner includes a thermoelectric device, and a first line with a first fluid therein. The first line is configured such that the first fluid can exchange heat with a first surface of the thermoelectric device, and configured to discharge the fluid to a space. A second line has a second fluid therein. The second line is configured such that the second fluid can exchange heat with a second surface of the thermoelectric device, and pass through a heat sink to further exchange heat. A control unit supplies electricity to the thermoelectric device such that the first surface absorbs heat in a cooling mode and the second surface absorbs heat in a heating mode. The control unit also controls a flow rate of the second fluid, such that the flow rate is higher in the cooling mode than in the heating mode.

Abstract: Sharp bends in a defrost duct extending from a defrost outlet to a windshield, and in a face duct extending from a face outlet to both sides of a front passenger seat, are eliminated and the duct resistance of these ducts is reduced. Moreover collision safety of passengers is improved, and an interior space of a vehicle is expanded forward. In an air-conditioning unit to be positioned to the front of a front seat of a vehicle, an evaporator is positioned below and behind a blower, and a heater core is positioned below and in front of the blower. Preferably the air-conditioning unit is of a crushable structure wherein, in the event of a vehicle collision, a wall of the main cover behind the evaporator is broken, or component parts housed within the main cover are moved, to thereby absorb the impact energy.