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.

A sealing assembly includes a fixation member and a sealing member connected to the fixation member. The fixation member is configured to be connected to a casing of a window air conditioner that is to be supported at a window and has an accommodation groove. The sealing member is configured to be sealingly arranged between a window sash of the window and an inner wall of the window. The window sash is at least partially extended in the accommodation groove.

The present disclosure is directed to implementation of an environmental control unit using rotomolded techniques to fabricate the structures of the unit instead of the standard conventional sheet metal, extruded, forged, and punched parts. Such implementations will provide a lighter weight and more durable mechanical configuration that will also simplify inspection, simplify assembly/disassembly, and reduce fabrication costs. Implementations incorporate rotationally-molded interlocking structures to contain and attach the critical items of the ECU's mechanical components including the compressor, and the indoor and outdoor coils, as well as the fan and blower motor assembly. In one implementation, the rotomolded structure is strengthened and insulated (thermally and acoustically) by filling the interior void of the rotationally molded structure with a closed-cell foam.

The present invention relates to an air-conditioning device comprising: a case having an interior divided into a first area and a second area, having an indoor inlet and an indoor outlet formed therein such that the first area and an indoor space communicate with each other, and having an outdoor inlet and an outdoor outlet formed therein such that the second area and an outdoor space communicate with each other; a barrier arranged between the first area and the second area inside the case; an indoor blowing fan arranged in the first area so as to form a flow of air from the indoor inlet to the indoor outlet; an outdoor blowing fan arranged in the second area so as to form a flow of air from the outdoor inlet to the outdoor outlet; a first thermoelectric element comprising a first indoor heat exchanger arranged in the first area so as to exchange heat with air passing through the first area, and a first outdoor heat exchanger arranged in the second area so as to exchange heat with air passing through the second area; a case lower-surface formed on the lower surface of the case so as to have an open upper side such that condensed water generated from the first thermoelectric element is collected; and a second thermoelectric element arranged between the first thermoelectric element and the case lower-surface so as to heat the condensed water. The first area and the second area are connected between the case lower-surface and the second thermoelectric element such that the condensed water is distributed across the first area and the second area. The present invention is advantageous in that indoor cooling/heating can be performed without no separate compressor, outdoor unit, and the like, and condensed water can be effectively evaporated.

A window air conditioner includes an indoor heat exchanger, a water receiving pan below the heat exchanger, and a filter screen. The water receiving pan includes mounting portions for connecting to heat exchanger flanges. At least one mounting portion has a slot to cooperatively receive a filter screen fitting portion.

An air conditioning apparatus for cooling and/or dehumidifying an interior space, such as the interior of a shelter or tent that provides for simplified manufacturing, simplified inspection and servicing, reduced noise, reduced vibration, reduced weight, increased ruggedness and health monitoring. Structural components of the apparatus are fabricated from foam-filled molded parts with interlocking components, and the unit is assembled and tested without any outside cover, but once the cover is installed, additional structural strength is obtained from the cover. A refrigerant flow sensor along with other sensors are used to determine actual real time cooling capacity measurements and health monitoring.

An indoor unit includes a main unit including an air inlet through which air enters from a room and an air outlet through which air blows into the room, an electrical component box mounted on an outer surface of the main unit and accommodating an electrical device, a refrigerant pipe connection portion to which a refrigerant pipe through which refrigerant passes is connected, a drain pipe connection portion to which a drain pipe through which drain water discharged from the main unit passes is connected, and an installation bolt attachment bracket mounted on the outer surface of the main unit and fixing the main unit to an installation bolt suspended from above a ceiling. The indoor unit has the refrigerant pipe connection portion, the drain pipe connection portion, and the electrical component box on the same mounting surface.

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 the window unit of indoor air conditioning device. The disclosed device is split into two sections, with one being inside a room and the other hanging outside of the exterior wall. The two sections are connected together via a conduit channel, which is also used as a low-profile conduit, using flexible piping. The flexible piping are breakingly coupled within the conduit using snap connectors or twist-off connectors. The conduit being placed over a windowsill, wherein the windowsill supporting the weight of both containers.

An air conditioning apparatus for cooling and/or dehumidifying an interior space, such as the interior of a shelter or tent that provides for simplified manufacturing, simplified inspection and servicing, reduced noise, reduced vibration, reduced weight, increased ruggedness and health monitoring. Structural components of the apparatus are fabricated from foam-filled molded parts with interlocking components, and the unit is assembled and tested without any outside cover, but once the cover is installed, additional structural strength is obtained from the cover. A refrigerant flow sensor along with other sensors are used to determine actual real time cooling capacity measurements and health monitoring.