A navigation device mounted on an electrically powered vehicle which includes a battery that supplies electricity to an electric motor and an air conditioner. The navigation device includes a controller. The controller is configured to obtain an electricity amount for traveling and an electricity amount for air conditioning, these electricity amounts are needed during travel from a current location to a destination specified by a user. The controller is configured to add the electricity amount for air conditioning to the electricity amount for traveling to obtain a total amount of electricity. When a remaining amount of electricity stored in the battery is less than the total amount of electricity, the controller operates a display to show a site where the vehicle is reachable with the remaining amount of electricity and is located between the current location and the destination, along with positional information on a charging spot around the site.

A method and a device for operating a multi-channel device wherein common control of an adjustment parameter is carried out in different zones in a synchronization mode. In another operating mode, the zones are controlled separately according to the individually adjusted adjustment parameters. There are at least a first parameter adjuster and a second parameter adjuster for setting the parameters for the at least two zones. The individual operating mode, on further actuating the second parameter adjuster so the selected parameter is brought into agreement with the parameter value selected by the first parameter adjuster, the second operating mode is exited and the at least two different zones are again controlled in common in the first operating mode.

A two-door HVAC air intake comprising an air intake body having a fresh air opening and first and second recirculated air openings is disclosed. A first door is provided that is movable from a first recirculation opening-unblocking/fresh air opening-blocking position to a first recirculation opening-blocking/fresh air opening-unblocking position. A second door is provided that is movable from a second recirculation opening-unblocking position to a second recirculation opening-blocking position. The doors may be shell doors or flap doors. Fresh air mode is achieved by moving the first and second doors to their recirculation opening-blocking positions. Partial air recirculation mode is achieved by moving the first door to its first recirculation opening-blocking position and the second door to its second recirculation opening-unblocking position. Full air recirculation mode is achieved by moving the first door to its first recirculation opening-unblocking/fresh air opening-blocking position and the second door to its second recirculation opening-unblocking position.

A seat air conditioner is applied to a seat disposed in a vehicle interior space and includes a seat back portion which supports an upper body side of a user and a seat cushion portion that supports a lower body side of the user. The seat air conditioner includes multiple air flow ducts provided in at least one of the seat back portion or the seat cushion portion and define an air flow passage for air to be blown out from the seat or air to be drawn into the seat. Some of the multiple air flow ducts are configured to be independent from the other air flow ducts such that air, which is different in temperature from the air flowing through the other air flow ducts, is allowed to flow through the some air flow ducts.

A cab for an agricultural working vehicle has a cab base and a cab roof, between which a windshield and side windows are situated in a frame structure, and a driver's seat situated on the cab base. There is at least one air treatment device for cooling and heating an inlet air flow which is supplied to the cab through an intake duct. The air treatment device has at least one first air distribution duct having at least one first air outlet opening, and at least one second air distribution duct having at least one second air outlet opening. The first air outlet opening outputs a first air flow substantially along the windshield and the second air outlet opening outputs a second air flow directed in the direction of the driver's seat. The first air flow has a higher temperature than the second air flow.

An air conditioning unit for a vehicle has a casing, a heating heat exchanger, a first partition plate, a first opening, a second partition plate, a second opening, and a switching door. The casing has a face opening and a foot opening. The heating heat exchanger is arranged in the casing. The first partition plate partitions a downstream side of the heating heat exchanger in an airflow direction into a first passage and a second passage located below the first passage. The first opening is formed on a downstream side of the first partition plate in an airflow direction and communicates between the first passage and the second passage. The second partition plate is arranged on the downstream side of the heating heat exchanger and is formed with a third passage between the first partition plate and the second partition plate in the first passage. The second opening that is located on a downstream side of the second partition plate in an airflow direction and communicates between an upper side and a lower side of the second partition plate. The switching door opens or closes the first and second openings. The air in the third passage is guided toward the foot opening by the second partition plate and the switching door in an air conditioning mode in which the switching door opens the first opening and closes the second opening.

A blower includes a fan that rotates about an axis center in an air conditioning case, and a casing that guides air blown from the fan. The casing has a peripheral wall that is located radially outward of the fan with the axis center as a center. The peripheral wall has first and second scroll inner wall surfaces that guide different kinds of air blown from the fan to different outlets. No half-lines starting from the axis center passes through both of the first and second scroll inner wall surfaces.

An air conditioner for a vehicle including a case body having a floor outlet, a roof outlet, an evaporator, and a heater core; a mode door adjusting an opening amount of each of the vents; and a temp door adjusting an opening amount of a cold-air passage and a hot-air passage, includes: an actuator lever connected to an actuator provided in the case body, and a main lever connected to the actuator lever to simultaneously control the mode door and the temp door.

The present invention provides a construction machine, which includes a cabin in which a driver is seated, the construction machine including a ventilated seat having fans, an air conditioning device configured to adjust an internal temperature of the cabin, and ducts extending from the air conditioning device and configured to guide an air flow, in which the ducts branches to include a first duct extending toward an upper side of the cabin, and a second duct extending toward a rear side of the ventilated seat. Therefore, it is possible to improve a cooling effect that the driver actually feels.

A humidity detector a humidity sensor detecting a relative humidity of an air inside a sensor case housing the humidity sensor. The humidity detector has an air volume obtaining section, a flow direction obtaining section, a setting section, and a correction section. The air volume obtaining section obtains air volume information correlated with an air volume of the air flowing around the humidity sensor. The flow direction obtaining section obtains flow direction information correlated with a flow direction of the air flowing around the humidity sensor. The setting section sets correction factors configuring a dynamic compensator based on the air volume information and the flow direction information. The dynamic compensator compensates for a response delay of the humidity sensor. The correction section corrects a detection value, which is detected by the humidity sensor, by using the dynamic compensator to obtain the relative humidity of the air.