The present utility model it is an air conditioner Split type, with application in environments cooling area, internal humidification system and water dispersion system in cool mist form to the external environment aiming to return the water was removal of the environment. Characterized by an air conditioner Split type (FIG. 2) with addition of a humidification system that uses metal diaphragms (item 2.g) vibrating at ultrasonic frequency to create water droplets, producing a cool mist (item 2.d) to be released in the external environment through the duet conductor (item 2.m) eliminated by the air conditioner and stored in the reservoir (item 2.n) located in the lower region of the evaporator unit. The humidification of the internal environment is controlled by a humidity meter that, when it reaches a level lower than recommended by the World Health Organization, dispense water in the form of cool mist, balancing the humidity in the indoor environment.

Disclosed herein is an air conditioner and a control method thereof. The air conditioner includes: a housing including a base, a first heat exchanger disposed inside the housing and configured to exchange heat with outdoor air, a second heat exchanger disposed inside the housing and configured to exchange heat with indoor air, a compressor configured to compress a refrigerant for a heat exchange operation performed by the first heat exchanger and the second heat exchanger, a first fan disposed inside the housing and configured to move air along a flow path passing through the first heat exchanger, a drainage device configured to move condensed water condensed on the second heat exchanger inside the housing and collected in the base to the first heat exchanger, and a controller including at least one processor, comprising processing circuitry, individually and/or collectively, configured to, based on the stop of the operation of the compressor, control the drainage device to move the condensed water collected in the base to the first heat exchanger during a drainage time determined based on an operation time of the compressor, and to control the first fan to move air during the drainage time.

A water receiving in an air conditioner is disclosed. Further, a water-receiving tray structure for an indoor unit of an air conditioner, an indoor unit and an air conditioner. The water-receiving tray structure includes a water-receiving tray, an elevating member and a fixed member; the indoor unit having a casing with a first end defining a return-air inlet and a second end opposite to the first end and defining the air outlet, the water-receiving tray being arranged in a direction from the return-air inlet to the air outlet and being located below a heat exchanger of the indoor unit; the elevating member being arranged at an air outlet end of the indoor unit and supporting an air outlet side of the water-receiving tray; the fixed member being arranged in the indoor unit and being connected to an air outlet side of the indoor unit.

An air conditioner circulation apparatus includes a receiving tank (2) provided with an air channel (22), an active carbon (3) mounted in the receiving tank, and an air blower housing (4) connected to the air channel. The receiving tank collects water drained from an air conditioner. A hot air drained from the air conditioner is sucked into the air blower housing, and is delivered through the air channel into the bottom of the receiving tank. The active carbon filters impurities in the hot air. The water collected in the receiving tank cools and returns the hot air into a cooled air which has a normal temperature, and purifies the cooled air to release a clean air. Thus, the water and the hot air drained from the air conditioner are removed, and the fresh clean air is generated.

Various air conditioner systems and methods are presented. An air ventilation chamber assembly may include a first chamber and a second chamber through which air is circulated into an environment to be cooled. A cooling element of a heat pump, may pass through the first chamber of the air ventilation chamber assembly, wherein the cooling element does not pass through the second chamber of the air ventilation chamber assembly. A Peltier cooler may be present that has a cold side and a hot side. The cold side may be is thermodynamically coupled with a surface of the second chamber.

Various embodiments of air conditioner units are detailed. Such air conditioner units may use multiple air ventilation chambers arranged on both an indoor and outdoor portion of the air conditioner unit. A through-unit window may be present that permits an unobstructed view through the air conditioner unit between the first air ventilation chamber and the second air ventilation chamber.

An air conditioner includes an indoor unit, an outdoor unit, and an inductor assembly. The indoor unit includes an indoor air duct component. The outdoor unit includes an outdoor air duct component. The indoor air duct component and the outdoor air duct component are spaced apart. The inductor assembly is located between the indoor air duct component and the outdoor air duct component, and includes an inductor box shell, an inductor and an inductor box cover. The inductor box shell has an accommodating space and includes a shell side plate, a first heat dissipation opening, a first water blocking portion, a shell top plate and a second heat dissipation opening. The inductor is disposed in the accommodating space. The inductor box cover is disposed on top of the inductor box shell, and includes a cover top plate, a third heat dissipation opening and a second water blocking portion.

Disclosed is a window air conditioner drain that includes a main body having a drain side and an interfacing side. The drain side includes a funnel structure that narrows to a tube attachment portion of the funnel structure. The window drain further includes a magnetic attachment mechanism configured for magnetically attaching the main body to a window air conditioner such that the main body covers a drainage hole of the window air conditioner. Further disclosed is a window air conditioner drain kit incorporating the window air conditioner drain, and a kit that includes the window air conditioner drain, magnets and/or a flexible tube.

An air conditioner unit is provided including a cabinet. The cabinet includes a front opening including an upper portion and a lower portion each forming a portion of a perimeter of the front opening. The lower portion includes a lower face. A lower handle extends from the lower portion at the lower face. A bulkhead is mounted within the cabinet to form an indoor portion and an outdoor portion. A refrigeration loop includes an outdoor heat exchanger positioned within the outdoor portion and an indoor heat exchanger positioned within the indoor portion. A compressor is operably coupled to the refrigeration loop and is configured for urging a flow of refrigerant through the outdoor heat exchanger and the indoor heat exchanger.

An air conditioning unit is disclosed herein. The air conditioning unit may include a compressor configured to pump a refrigerant, a valve configured to receive the refrigerant from the compressor, a heat exchanging coil configured to receive the refrigerant from the valve in a defrosting mode and melt ice formed on the heat exchanging coil into condensate, a drip pan arranged to receive the condensate from the heat exchanging coil, a heating element disposed within the dip pan so as to heat the condensate received in the drip pan, and a condensate pump configured to pump the condensate from the drip pan.