Abstract: An active material container for a functional housing has an air-permeable casing with an interior and an active material arranged inside the interior. One or more rim-side guide elements are arranged at the air-permeable casing and are provided to linearly slidably guide the active material container in an insertion direction in corresponding guide elements of a receptacle of the functional housing. The functional housing is preferably a battery housing.

Abstract: An air conditioner for a vehicle includes a casing that forms an air passage through which air flows, a blower fan to blow out air, and a heating device to heat air. The casing includes a passage portion through which air flows, a warm air passage that allows air to flow to the heating device, and a bypass passage that allows air to bypass the heating device. A width dimension of the passage portion in a second direction is larger than that of the heating device in the second direction, and is smaller than a height dimension of the passage portion in a first direction.

Abstract: A heat exchanger includes multiple tubes, multiple fins, and a partition wall. The multiple fins are stacked alternately with the tubes to form a core including a first section and a second section. The partition wall partitions between the first section and the second section. The first section has multiple drain passages in the vicinity of the partition wall.

Abstract: An air conditioning apparatus has, a first domed door comprising a first pivot and a first sealing surface, and a second domed door comprising a second pivot and a second sealing surface, wherein, said second pivot is positioned different from said second pivot. With the above structure, the radial gap between the first sealing surface and the second sealing surface is varied when at least one of the two domed doors is moved. Accordingly, the air conditioning apparatus described above does not have to set the constant small radial gap or constant wide radial gap for the sake of reducing unintentional air leaking or preventing said friction.

Abstract: Provided are methods for decontamination of compartments, such as aircraft compartments and other types of compartments, and systems for implementing these methods. In some embodiments, a method involves detecting presence of one or more contaminants in a compartment. This information is used to select various decontamination conditions. In some embodiments, additional information, such as the type of the compartment (e.g., an aircraft compartment), temperature, and humidity, may be also considered while selecting the decontamination conditions. The decontamination conditions include identification of one or more decontaminating agents to be dispensed in the compartment, temperature profile of the air to be flown into the compartment, and timing of the decontaminant dispensing and air flowing operations. These conditions are selected to increase efficacy of the selected decontaminating agents with respect to the one or more detected contaminants and reduce impact on the aircraft compartment.

Abstract: The heating-ventilation and/or air-conditioning device for a motor vehicle passenger compartment comprises modules grouped substantially at the same horizontal level, namely at least one ventilation module (14) arranged to produce a pulsed air flow, a heating module (12) to be located in a central region of the passenger compartment and having heat exchangers (32, 34, 36) through which the air flow from the ventilation module can pass, and at least one distribution module (16) having an air inlet connected to a side air outlet (46d, 46g) of the heating module. The device of this invention may be installed in a vehicle passenger compartment having no central console.

Abstract: In an air conditioner casing of a vehicular air conditioner, an evaporator is arranged in a cold air passage, and a heater core is arranged in a warm air passage downstream from the cold air passage. A first air mixing damper is disposed in a warm air opening between the cold air passage and the warm air passage, and a second air mixing damper disposed in a cold air opening between the cold air passage and a bypass passage. Switching from a cooling mode to a heating mode, the first air mixing damper is opened at a constant speed proportional to the driving angle of a drive unit, and the second air mixing damper is initially rotated at a high speed by a predetermined angle immediately after the start of the closing operation, and thereafter is rotated at a low speed.

Abstract: A heating and air conditioning device for motor-vehicles, comprises a unit for suctioning and supplying air (13) and a heating and air conditioning unit (1), including a heater (2) and an evaporator (3) and a mixing lid (4) for distributing the airflow coming from the supply unit (13) between said heater (2) and said evaporator (3). The heating and air conditioning unit comprises a single moveable element for distributing the conditioned airflow between one or more outlets arranged along a dashboard of a motor-vehicle, respectively adjacent to the windscreen, at the front on the dashboard or adjacent to the floor of the cabin of the motor-vehicle, to respectively actuate the DEFROST, VENT, FLOOR functions or their combination. At least part of the air supply unit (13), preferably at least one air intake (14) and one pipe (15) for supplying air including an air filter (16), and borne by a bodywork connected to a front bonnet (22) of the motor-vehicle which closes the engine compartment at the upper part.

Abstract: A radiant heat raised access floor panel is provided. The panel includes a panel core. The core has four corner portions, four lateral edge portions, an upper load bearing surface, a lower plenum surface, a heating element, and an electrical connector in the lower surface adapted to connect to a pedestal head of a raised floor pedestal support system. A power and control circuit is in electrical communication with said connector and is adapted to variably and radiantly heat a predetermined lower occupied zone of an underfloor air distribution system.

Abstract: The present technology relates to a heating, ventilation, and air conditioning (HVAC) system for a motor vehicle with supplemental thermal storage, the HVAC system having a length greater than a width and disposed with the length parallel to a longitudinal axis of the motor vehicle between the front seats thereof. The HVAC system includes a blower assembly disposed beneath an instrument panel of the motor vehicle or inside an engine compartment. A thermal storage device in thermal communication with air caused to flow through the HVAC system.

Abstract: The invention relates to a heating, ventilation, and air conditioning (HVAC) system for a motor vehicle, the HVAC system having a length greater than a width and disposed with the length parallel to a longitudinal axis of the motor vehicle and between the front seats thereof. The HVAC system includes a plurality of heat exchangers disposed within a housing thereof.

Abstract: A heating, ventilation and/or air-conditioning apparatus (1) for the passenger compartment of a motor vehicle includes a housing (2) comprising a first air inlet (3) and a second air inlet (4). The housing (2) directs an inner air flow (Fi) from the first air inlet (3) and/or the second air inlet (4) and contains at least a first heat exchanger (5). The housing (2) includes: an air flow channel (24) directing the inner air flow (Fi) in the housing (2) while bypassing the first heat exchanger (5); and an air inlet duct (23) directing the inner air flow (Fi) in the housing (2) through the first heat exchanger (5). A heating, ventilation and/or air-conditioning installation for the passenger compartment of a motor vehicle includes: an air conditioning loop through which a coolant flows. The loop includes at least one compressor, a first expansion member, an outer heat exchanger and the first heat exchanger (5). The installation also includes the heating, ventilation and/or air-conditioning apparatus (1).

Abstract: An electrical heater for vehicle windshields and windows includes a heating chamber having heat reflective interior walls and at least one electrically driven heater element so as to produce heat from the element when energized, wherein the heater circuit wiring is adapted to only be electrically connected to a conventional DC electrical system of a vehicle, and wherein the heating chamber is adapted to be mounted under the windshield vents of the vehicle to thereby direct airflow flowing over the heater elements as forced by the vehicle's heater core fan through the vehicle ducting and out from the vehicle's windshield vents.

Abstract: An air conditioner for a vehicle in which an operational efficiency of an in-vehicle equipment is controlled, includes a first heating portion which heats air to be blown into a vehicle compartment by using heat medium, a second heating portion which heats the blown air by using heating energy outputted from the in-vehicle equipment, a determination portion which determines a target heat amount ratio that is a target value of a heating amount ratio of a second heat amount used in the second heating portion to a first heat amount used in the first heating portion, and a heating adjustment portion which adjusts at least one of the first and second heat amounts such that the heat amount ratio approaches the target heat amount ratio. The target heat amount ratio is increased in accordance with an increase of the operational efficiency.

Abstract: Provided is an anti-fog and HVAC system (30, 30A, 30B) for an electric vehicle, which is configured to dehumidify air inside the electric vehicle, the anti-fog and HVAC system including: a unit casing (1K) formed into a rectangular parallelepiped shape with a hollow interior, the unit casing (1K) containing a dehumidifying unit (1) removably storing a dehumidifying cassette (3) containing a dehumidifying member (2); an inlet duct (7) for guiding the air inside the electric vehicle to an input side of the unit casing (1K); and a ventilation duct (5) for discharging, into the electric vehicle, dehumidified air from an output side of the unit casing (1K).

Abstract: A system described is for providing improved cabin heating. The system may include a vehicle cabin heating system having a first and second heating system receiving coolant flow from the engine; and a control system for operating the engine at a first engine idle speed upon entering idle speed control operation from previous drive operation, maintaining said first idle speed for a duration, and then increasing engine speed to increase coolant flow to the second heating system during cold ambient conditions when the second heater system is in operation.

Abstract: There are provided a blowing-mode door for a vehicle air-conditioning apparatus in which leakage of temperature-adjusted air can be prevented to improve independent temperature-adjusting performance by minimizing the gap between the mode door and a partition plate and increasing the rigidity of the mode door, as well as a vehicle air-conditioning apparatus using the same. A blowing-mode door applied to a vehicle air-conditioning apparatus with an independent temperature-adjusting system is provided in which the blowing-mode door includes a rotating shaft having a predetermined length and a pair of left and right plate-like doors that are molded integrally with the rotating shaft, with a gap for preventing interference with a partition plate therebetween.

Abstract: In an air conditioning case of an air conditioner, an air mixing chamber, a warm-air bypass passage, a first warm-air passage and a second warm-air passage are provided. The warm-air bypass passage is located in a part of space, in which the air mixing chamber is provided, and the second warm-air passage is located at an opposite side of the first warm-air passage with respect to the air mixing chamber. The warm air flowing in the warm-air bypass passage makes a U-turn at the second warm-air passage and flows toward the air mixing chamber. Therefore, in the air mixing chamber, the cool air is inserted between the warm air from the first warm-air bypass passage and the warm air from the second warm-air passage, from two sides of the cool air.

Abstract: An air conditioner for a vehicle includes an electric heater arranged downstream of a heat exchanger in an air flow direction, a defroster air outlet, a driver-foot air outlet through which air is blown toward a foot area of a driver, a knee air outlet through which air is blown toward a knee area of the driver, a door device which controls an air amount blown into a vehicle compartment by opening or closing the air outlets. When an immediate heating operation is performed by an operation of an immediate heating switch, the door device opens the defroster air outlet and at least one of the driver-foot air outlet and the knee air outlet, and the electric heater heats a total amount of air that is to be blown through the at least one of the driver-foot air outlet and the knee air outlet.

Abstract: A process for removing or treating harmful biological and organic substances within an enclosure includes heating the ambient air within the enclosed area to a predetermined temperature over time to cause harmful biological or organic substances to be destroyed or migrate into the ambient air. Temperature and pressure levels are monitored through the treatment process. Contaminated objects or areas may be subjected to biocides, irradiation, or even freezing as part of the treatment process. The air removed from the enclosure is preferably passed through an incinerator, a filter or an irradiation device and the heated air is re-circulated to enhance efficiency.

Abstract: A system and process is provided for removing or treating harmful biologic and organic substances within an enclosure, such as a container, building or vehicle. Air within the enclosure is heated to a predetermined temperature to kill organisms and cause harmful substances in the structure to migrate into the ambient air. Boric acid in combination with the heat may be used to kill mold and similar undesirable organisms. Temperature and pressure levels are monitored. The heated air carrying the harmful substances is passed through a filter to remove the harmful substances, and the heated air is re-circulated to enhance efficiency. The system effectively kills insects, molds, viruses and bacteria and reduces the levels of allergens and volatile organic compounds in the structure.

Abstract: An apparatus for providing pollution free air to an individual includes an enclosed or semi-enclosed space or compartment for surround or partially surrounding an individual's head or upper body to separate the individual from polluted air. A filter assembly and fan forcing polluted air through the filter assembly and into the enclosure. The filter assembly includes a first filter for removing relatively large particles such as sand or dust from the polluted air while a second HAPA filter removes airborne allergens before forcing non-polluted air into the enclosed or semi-enclosed space.

Abstract: 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.

Abstract: A thermal conditioning system for the energy storage system of a hybrid vehicle. At least one auxiliary air source, other than a permanently open air source, has a selectively operable actuator door which either connects or disconnects the auxiliary air source to the energy storage system blower, the air flow being selected to optimally temperature condition the energy storage system. The auxiliary air source preferably includes the HVAC ducting.

Abstract: An automotive vehicle has a passenger cabin, an HVAC system adjustable between a fresh air mode and a recirculate mode, a compartment containing a heat-producing electrical component, and a non-passenger compartment that is ventilated to outside of the vehicle. A duct has an inlet end adjacent the compartment and an outlet end adjacent an air intake of the HVAC system. A valve controls whether cooling air exiting the compartment is directed into the duct or into the non-passenger compartment. The valve is operated to direct a majority of the cooling air into the duct when the HVAC system is in the recirculate mode, and into the non-passenger compartment when the HVAC system is in the fresh air mode. Air from the non-passenger compartment may be vented out of the vehicle through an air extractor vent.

Abstract: The present invention provides an air conditioning system for an electric vehicle and a method of controlling the air conditioning system. According to preferred embodiments, the air conditioning system includes a blower, a battery and a Motor Control Unit (MCU), and a controller.

Abstract: An automotive air conditioning system is disclosed. At the foot mode position of a rotary door 25, a gap T is formed along the door diameter between a circumferential end of a door surface 25c of the rotary door 25 and a seal rib 28 of a case 11. The flow path of a foot opening 22 communicates with a defroster opening 20 through the gap T. At the defroster mode position of the rotary door 25, on the other hand, the other circumferential end of the door surface 25c comes into contact with the seal rib 28 and closes the gap T, and the door surface 25c closes up the foot opening 22. Even upon slight rotation of the foot rotary door under the air pressure of the foot mode, therefore, the defroster blowout air amount and the foot blowout air amount are kept in a predetermined proportion.

Abstract: The present invention provides an air conditioning system for an electric vehicle and a method for controlling the same in which heat generated from a drive motor during vehicle running is used to assist the heating of a vehicle interior so as to provide more efficient heating of the vehicle interior and, especially, reduce the amount of battery power consumed for the heating of the vehicle interior, thus increasing driving distance and improving fuel efficiency. The air conditioning system of the invention can cool the drive motor, heat the vehicle interior using waste heat of the drive motor, and purify the air supplied to the vehicle interior with the use of a single blower.

Abstract: An air purification system for a vehicle may comprise a first heated-ambient-air source comprising an engine with an ambient air compressor; and at least one heated-ambient-air outlet. The system may also comprise a second heated-ambient-air source; a mixing valve; a first heated-ambient-air channel connected between the at least one heated-ambient-air outlet of the engine and the mixing valve; a second heated-ambient-air channel connected between the second heated-ambient-air source and the mixing valve; and a catalytic decontamination unit positioned between the mixing valve and an enclosed passenger cabin of the vehicle for removing contaminants from ambient air and producing decontaminated air to the enclosed passenger cabin.

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 HVAC system for a vehicle includes a housing, a front HVAC unit housed in the housing and having a front blower, a first airflow path, and a front air mix door, a rear HVAC unit housed in the housing and having a rear blower, a second airflow path, and a rear air mix door. The HVAC system further includes an evaporator having a first portion disposed in the first airflow path and a second portion disposed in the second airflow path, and a heating core having a first portion disposed in the first airflow path and a second portion disposed in the second airflow path. An airflow directional door is disposed between the first airflow path and the second airflow path to regulate airflow from the rear blower to the first airflow path.

Abstract: A dual-integrated HVAC system for an automotive vehicle is provided that includes a housing, a front HVAC unit with a front blower, and rear HVAC unit with a rear blower whereby both the front and rear HVAC units are housed in the housing. The front blower generates an airflow through a front airflow path and the rear blower generates an airflow through a rear airflow path. A separating wall separates the front airflow path from the rear airflow path. The HVAC system further includes an evaporator with a first portion in the front airflow path, a second portion in the rear airflow path, and a seal situated between the first portion and the second portion.

Abstract: An apparatus for providing convenience services to a stationary vehicle independent of the vehicle's electrical system. At least one conduit is attached to a housing for transferring the services to a supply panel. The supply panel includes a face on which the various controls and connectors associated with the supplied convenience services, such as heating, cooling, electrical power, compressed air, computer network communications, telephone, video, and television, are disposed. The supply panel is dimensioned to interface with the stationary vehicle through an opening in the vehicle, such as a window or service door, and includes means for providing a substantially airtight seal for climate control.

Abstract: A passive air valve for an HVAC module allows air to flow through a conditioning passage in a single direction. The valve can be disposed on a downstream side of a heat exchanger. The valve can inhibit back airflow from one of the conditioning passages to the other one of the conditioning passages.

Abstract: An apparatus for providing convenience services to a stationary vehicle independent of the vehicle's electrical system. At least one conduit is attached to a housing for transferring the services to a supply panel. The supply panel includes a face on which the various controls and connectors associated with the supplied convenience services, such as heating, cooling, electrical power, compressed air, computer network communications, telephone, video, and television, are disposed. The supply panel is dimensioned to interface with the stationary vehicle through an opening in the vehicle, such as a window or service door, and includes means for providing a substantially airtight seal for climate control.

Abstract: There are provided a blowing-mode door for a vehicle air-conditioning apparatus in which leakage of temperature-adjusted air can be prevented to improve independent temperature-adjusting performance by minimizing the gap between the mode door and a partition plate and increasing the rigidity of the mode door, as well as a vehicle air-conditioning apparatus using the same. A blowing-mode door applied to a vehicle air-conditioning apparatus with an independent temperature-adjusting system is provided in which the blowing-mode door includes a rotating shaft having a predetermined length and a pair of left and right plate-like doors that are molded integrally with the rotating shaft, with a gap for preventing interference with a partition plate therebetween.

Abstract: A climate control system is provided that includes blowers, in particular in agricultural or construction machinery, having at least two blowers, at least one fresh air/circulating air conduit, at least one circulating air/intake air conduit, an evaporator and, if required, a heater, the evaporator and heater being situated on the air downstream side of the blowers, the blowers being situated at substantially the same height, viewed in a longitudinal direction of the vehicle. The first blower drawing in fresh air from at least one fresh air opening in the rear area of the vehicle, and the second blower drawing in at least circulating air from the vehicle interior from at least two circulating air openings situated on opposite sides of the vehicle, and at least one circulating air/intake air conduit running above and/or below the first blower and leading to the second blower from the circulating air opening on one side of the vehicle interior.

Abstract: A control unit of a vehicular air conditioning apparatus calculates a front target temperature, a rear target temperature, and a reference air volume level based on a deviation between the front target temperature and the rear target temperature. The control unit further calculates a correction amount for correcting the reference air volume level based on a deviation between the front target temperature and the rear target temperature.

Abstract: An air control device suitable for use in a heating and/or air-conditioning system comprises an air control member having a portion capable of selectively blocking the flow of air in an air passageway, a shaft member connected to the selective air blocking portion and having an axis about which the selective air blocking portion rotates, and a portion located on at least one end of the shaft that comprises a mechanism for inter-engaging with an actuating device for rotation of the shaft member; wherein the shaft end has at least first and second different mechanical configurations, wherein each configuration is capable of selectively interacting with a different type of actuation device.

Abstract: The invention relates to an air-conditioning device (10) which is used to air-condition an area, in particular the passenger compartment of a motor vehicle, comprising a heat exchanger which can be cross-flown by air, which is to be air-conditioned, and which is arranged inside an air guiding channel (12), wherein a cross-flowable heating device (18) is arranged downstream therefrom. According to the invention, the air guiding channel (12) extends in a deviation free manner and in an essentially linear direction between the heat exchanger (16) and the heating device (18).

Abstract: A vehicular air-conditioning apparatus includes a hot-water heater and an electric heater provided downstream of the hot-water heater. The apparatus also includes a bypass passage for allowing air-conditioning air flowing past the hot-water heater to bypass the electric heater and a bypass door provided in the bypass passage for opening and closing the bypass passage.

Abstract: An HVAC assembly including an HVAC case disposed in a passenger compartment of a vehicle for delivering air at a passenger side foot well includes a duct coupled to an opening on the HVAC case. The duct is configured to deliver air from the HVAC case to the passenger foot well. The passenger foot well is defined by a front boundary, a lower boundary and two side boundaries. The duct includes an input coupled to the opening on the HVAC case and accepting air into an upstream portion having a single passage. The upstream portion directs air in a generally upward direction away from the lower boundary of the passenger side foot well. The duct further includes an intermediate portion whereby the single passage divides into a first and second passage. A first and second outlet is coupled to and downstream of the first and second passage and dispense air at the passenger side foot well.

Abstract: A method regulates a heating and/or air-conditioning system, with a control apparatus which activates the individual air-conditioning components according to control and regulating programs. The vehicle interior has individual air-conditioning zones which can be regulated individually in terms of their air-conditioning capacity by the general air-conditioning regulation. An air-conditioning deficit of each individual air-conditioning zone can be detected, and the general air-conditioning regulation of the heating and/or air-conditioning system can set this air-conditioning zone independently. One or more central or decentralized additional-heating and/or cooling elements are included.

Abstract: A solar powered heating and ventilation system maintains an unoccupied vehicle at a more comfortable temperature relative to the outside temperature using both heating and cooling as appropriate. The system uses an air duct having a fan, heating element, vents, flaps, a selector switch, power control circuitry, a thermostat, and a clock/timer. The system also uses an electronic solar power panel and battery as power sources. The thermostat senses air temperature and causes the power control circuitry to regulate the temperature. The clock/timer may be manually set to activate and/or deactivate the power control circuitry at predetermined times. The system provides power to the fan and heating elements via a selector switch and power control circuits. The power control circuitry is connected to the vehicle battery and electronic solar power cells. The duct is located on the interior ceiling of the vehicle and has at least three vents.

Abstract: In an air conditioning unit of a vehicle air conditioner, an air-outlet mode switching portion is provided at an upper side of a heat exchanging portion including at least a heating heat exchanger for heating air. The air-outlet mode switching portion includes a rotary door rotatable around a rotation shaft, and the rotary door includes a circumference wall surface for opening and closing plural air outlet openings through which air is blown toward different zones of a passenger compartment. Further, the heating heat exchanger is arranged to be crossed with a horizontal surface, and a rotation space of the rotary door is provided to extend from an upper side of the heating heat exchanger to a side portion of the heating heat exchanger. Accordingly, the size of the air conditioning unit can be made smaller.

Abstract: In a deodorizing apparatus for a vehicular passenger compartment, when an ignition key is of f and it is determined that a density of odor components in the passenger compartment is equal to or higher than a predetermined level, it is determined whether an inside temperature inside the passenger compartment measured by a temperature sensor is equal to or higher than a predetermined temperature, which is suitable for separating odor components adhered to the passenger compartment. When it is determined that the inside temperature is equal to or higher than the predetermined temperature, a deodorizing operation is performed by a deodorizing means. When it is determined that the inside temperature is lower than the predetermined temperature and it is not assumed that the inside temperature naturally increases to the predetermined temperature, the passenger compartment is heated by a compartment heating device so that the inside temperature reaches the predetermined temperature.

Abstract: A solar powered heating and ventilation system maintains an unoccupied vehicle at a more comfortable temperature relative to the outside temperature using both heating and cooling as appropriate. The system uses an air duct having a fan, heating element, vents, flaps, selector switch and power control circuits. The system also uses an electronic solar power panel and battery as power sources. The system provides power to the fan and heating elements via a selector switch and power control circuits. The power control circuits are connected to the vehicle battery and electronic solar power cells. The duct is located on the interior ceiling of the vehicle and has at least three vents.

Abstract: A ventilation controlling apparatus using a slide door made of a flexible film member to solve imperfect slide action attributable to film member rigidity degradation on the fringe of an aperture. The slide door is movably disposed inside a casing which forms an air passage, and the slide door is composed of the flexible film member provided with an air-circulation aperture. Ventilation of the air passage is controlled by varying an area of blending or connection between the aperture and the air passage in accordance with movement of the slide door. A rigid support member is fitted around the fringe of the aperture on the film member, thereby enhancing rigidity of the aperture fringe.

Abstract: The present invention relates to an air flap (10) for an air-ducting device, in particular a vehicle heating, ventilation and/or air-conditioning system, with at least two ducts (2, 4), which have a common outlet zone, comprising a region (12) which allows part of the outlet zone to be divided in a sealed manner in each position of the air flap (10), the region (12) being smaller than the area of the air flap.

Abstract: The mixing device, for distributing in variable proportions a main air stream (8) flowing through an apparatus for heating and/or air-conditioning the cabin of a motor vehicle between a hot air duct (14) and a cold air duct (18), comprises a perforated panel (40) arranged in the hot duct (14) and a shut-off plate (44) that can move between an open position in which it is spaced away from the perforations (42) in the panel (40) and a shut-off position in which it shuts off the panel, a shutter (50) for adjusting the passage cross section of the cold air duct (18) that can move between an open position and a shut-off position, a control mechanism (54) for controlling, in synchronism, the movement of the shut-off plate (44) and the movement of the shutter (50).