A wireless controller (200) is configured to send commands to a mini-split HVAC unit (100) that thermostatically controls a temperature in a space (50) using the temperature sensed and a programmable set point. The wireless controller (212) may include an infrared (IR) transmitter (208), a temperature sensor (210), a user interface (214), a non-volatile memory (202), and a controller (212). The wireless controller (200) may store an IR database in the non-volatile memory (202) for each of a wide variety of mini-split HVAC unit (100). The wireless controller (200) may then allow a user to select a particular mini-split HVAC unit (100), and from the selection may identify a corresponding IR protocol in the IR database. During subsequent use, the wireless controller (200) may use the corresponding IR protocol during subsequent communication with the mini-split HVAC unit (100).

A wireless controller (200) is configured to send commands to a mini-split HVAC unit (100) that thermostatically controls a temperature in a space (50) using the temperature sensed and a programmable set point. The wireless controller (212) may include an infrared (IR) transmitter (208), a temperature sensor (210), a user interface (214), a non-volatile memory (202), and a controller (212). The wireless controller (200) may store an IR database in the non-volatile memory (202) for each of a wide variety of mini-split HVAC unit (100). The wireless controller (200) may then allow a user to select a particular mini-split HVAC unit (100), and from the selection may identify a corresponding IR protocol in the IR database. During subsequent use, the wireless controller (200) may use the corresponding IR protocol during subsequent communication with the mini-split HVAC unit (100).

A hybrid window air conditioning unit is disclosed. The hybrid window air conditioning unit may include an indoor unit and an outdoor unit operatively connected by a connection unit. The connection unit may have an interior channel containing refrigerant piping and electrical wiring connecting between the indoor unit and the outdoor unit. In some embodiments, the hybrid air conditioning may include a height-adjustable outdoor unit mounting assembly to allow the outdoor unit to be disposed substantially flush with or below a window.

An oil return control method for a multi-split air conditioner and a system accomplishing the same includes: calculating an average exhaust pressure within an oil return period Pd_AVG; determining whether the average exhaust pressure Pd_AVG≥the set threshold Pd.sub.threshold; if Pd_AVG≥Pd.sub.threshold, maintaining the multi-split air conditioner working in heating mode to ensure an acceptable oil return performance without affecting the air conditioning effect of indoor unit in heating mode; if Pd_AVG<Pd.sub.threshold, switching the multi-split air conditioner to cooling mode, stopping a fan within those power-on indoor units and entering into a cooling oil return process and switching the multi-split air conditioner back to heating mode until the cooling oil return process ends.

An air-conditioning system includes a refrigerant system in which an outdoor unit, one or more indoor units, and one or more ventilators are connected by a refrigerant pipe and in which refrigerant circulates, and a control device configured to control the refrigerant system. The control device includes a target temperature adjustment unit configured to adjust a target evaporating temperature based on a detection value detected by a temperature and humidity detection unit provided to at least one of the indoor unit and the ventilator that satisfies a specific criterion, and an air-conditioning control unit configured to control the refrigerant system such that the evaporating temperature of each of the indoor unit and the ventilator is equal to the target evaporating temperature adjusted by the target evaporating temperature.

An air-conditioning system includes a refrigerant system in which an outdoor unit, one or more indoor units, and one or more ventilators are connected by a refrigerant pipe and in which refrigerant circulates, and a control device configured to control the refrigerant system. The control device includes a target temperature adjustment unit configured to adjust a target evaporating temperature based on a detection value detected by a temperature and humidity detection unit provided to at least one of the indoor unit and the ventilator that satisfies a specific criterion, and an air-conditioning control unit configured to control the refrigerant system such that the evaporating temperature of each of the indoor unit and the ventilator is equal to the target evaporating temperature adjusted by the target evaporating temperature.

There is disclosed an outdoor unit comprising a case provided to define an exterior design and comprising a plurality of side panels having an inlet hole providing a path for sucking external air, a base plate supporting the plurality of the side panels, an upper panel having an outlet hole for discharging the external air sucked via the inlet hole to the outside; a heat-exchanger provided in the case and configured to exchange heat with the external air sucked via the inlet hole; a sliding plate slidingly provided in the base plate and supporting the compressor module and movable via the opening to expose the compressor module outside the case; and a compressor module configured to supply a refrigerant that exchanging heat with the external air to the heat-exchanger, such that the compressor module may be manipulative outside and demounted when the sliding plate is located in the exposure position.

An air conditioning unit comprising a bracket configured to be coupled to a sill of an opening between a first and second environment, the bracket comprising a pivot arm configured to be disposed and extending within the first environment. The bracket is configured to have a first unit positioned on top of the bracket; have the first unit moved on top of the bracket onto the pivot arm; and have the pivot arm and first unit rotated downward so that the first unit is disposed in the first environment and extending downward below the sill of the opening to cause one or more pivot arm guide slots of the pivot arm to rotate from a first configuration to a second configuration.

An air conditioning unit comprising a bracket configured to be coupled to a sill of an opening between a first and second environment, the bracket comprising a pivot arm configured to be disposed and extending within the first environment. The bracket is configured to have a first unit positioned on top of the bracket; have the first unit moved on top of the bracket onto the pivot arm; and have the pivot arm and first unit rotated downward so that the first unit is disposed in the first environment and extending downward below the sill of the opening to cause one or more pivot arm guide slots of the pivot arm to rotate from a first configuration to a second configuration.

The present disclosure relates to a method of controlling operation state of multi-split air conditioner and system, and a heat pump multi-split. The control method includes: determining a target operation mode of each indoor unit according to an operation mode set by a user for the indoor unit; performing statistics on heat exchange demands of the indoor units corresponding to different target operation modes, and determining a dominant operation mode among the target operation modes according to the heat exchange demands; and using the dominant operation mode as the operation mode of an outdoor unit.