Abstract: The disclosure discloses a variable refrigerant flow (VRF) air conditioning system with dual control over temperature and humidity and a control method thereof, in which the VRF air conditioning system includes multiple indoor machines, an outdoor machine and a controller; the outdoor machine is provided with a first connector and a second connector; each indoor machine includes an indoor throttle valve, a first heat exchanger, a second heat exchanger, a first solenoid valve, a second solenoid valve, a third solenoid valve, a temperature detector and a humidity detector; the controller controls the VRF air conditioning system by controlling the indoor throttle valve, the first solenoid valve, the second solenoid valve and the third solenoid valve in each indoor machine.

Abstract: A six-way directional valve (100), an outdoor unit (1000) having the same and an air conditioner are provided. The six-way directional valve (100) includes: a valve body (1), defining a valve cavity (5) therein, the valve cavity (5) having a first side wall (11) and a second side wall (12) disposed oppositely to each other, the valve body (1) being provided with a first connecting pipe (A) to a sixth connecting pipe (F); a valve spool (2), movably disposed in the valve cavity (5), a first chamber (21) being defined between the valve spool (2) and the first side wall (11), a second chamber (22) being defined between the valve spool (2) and the second side wall (12), and a third chamber (23) being defined between the valve spool (2), the first side wall (11) and the second side wall (12); and a pilot valve assembly (4).

Abstract: The present disclosure relates to a field of air blowing technologies of evaporators, more particularly to an evaporator baffle structure, an evaporator and an air conditioner. The evaporator baffle structure is configured as a V-shaped structure, in which two branches of the V-shaped structure are provided with a length-adjustable baffle separately, and a side of the V-shaped structure away from an opening thereof is provided with an evaporator mounting member. The evaporator includes an evaporator body and an evaporator baffle structure, in which the evaporator body is configured as an A-shaped structure, and the evaporator baffle structure is disposed at a top end of the evaporator body. The air conditioner includes the evaporator.

Abstract: In an air conditioning system of the present disclosure, the controlling module determines state of the indoor unit. If the indoor unit is under off state, the controlling module determines whether an indoor temperature is smaller than a preset temperature. If yes, the controlling module controls the indoor unit to heat according to a first heating temperature. If the indoor unit is under heating state, the controlling module sets a second heating temperature of the indoor unit to the first heating temperature, and controls the indoor unit to heat according to the first heating temperature. The first heating temperature is smaller than the second heating temperature. If the indoor unit is under cooling state, the controlling module sets a first cooling temperature to a second cooling temperature which is greater than the first cooling temperature, and controls the indoor unit to cool according to the second cooling temperature.

Abstract: A method for controlling an air conditioning system, an outdoor apparatus of an air conditioning system and an air conditioning system are provided. The method includes: obtaining a working mode of the air conditioning system and starting a variable-frequency compressor in an outdoor apparatus of the air conditioning system according to the working mode; obtaining a target refrigerant saturation temperature; performing a variable-frequency control on the variable-frequency compressor according to the target refrigerant saturation temperature; during the variable-frequency control, obtaining a working time of the variable-frequency compressor and a stop-start number of time of the variable-frequency compressor in a first predetermined period; and adjusting the target refrigerant saturation temperature according to the working time of the variable-frequency compressor and the stop-start number of time of the variable-frequency compressor in the first predetermined time.

Abstract: The present disclosure provides a method and a device for adaptively regulating a static pressure of a ducted air conditioner, and a ducted air conditioner. The method includes: dividing the static pressure in an air duct into a preset number of sections; selecting the sections i and i+1, and detecting respectively the gears corresponding to the sections i and i+1, the rotating speeds Ri and Ri+1, and an actual working currents Ii and Ii+1; and judging whether Ii and Ii+1 are within the normal current ranges respectively; and selecting the final section according to the judging result. With the method, the air duct conditioner may automatically select and determine a section according to actual installation environments, and may automatically determine an optimum section in which the ducted air conditioner works.

Abstract: A communication converting apparatus for a pulse meter is provided, comprising: a pulse collection unit, configured to collect a pulse signal generated from the pulse meter; a storage unit, configured to store a reading of the pulse meter; a micro control unit, configured to control the pulse collection unit to collect the pulse signal, to read the reading stored in the storage unit, and to obtain an updated reading of the pulse meter according to the pulse signal and the reading stored in the storage unit; and a RS485 communication unit, configured to covert the updated reading of the pulse meter into a RS485 communication signal for outputting.

Abstract: A heat exchanger and a gas-fired furnace including the same are provided. The heat exchanger includes at least two heat exchange shell enclosures; and at least three rows of heat exchange tubes arranged along a furnace air flow path. Each of the heat exchange tubes defines a leaving-tube-end and an entering-tube-end, two adjacent rows are spaced from each other, the at least three rows of heat exchange tubes are connected in a leaving-tube-end to entering-tube-end fashion sequentially via the at least two heat exchange shell enclosures to define a substantially serpentine flue gas passage.

Abstract: A water tank may include an inner tank and a condenser. The condenser may have a liquid inlet tube, a liquid outlet tube, first and second condensing tubes wound around respectively an outer wall of an upper and lower part of the inner tank, first ends of the first and second condensing tubes being in fluid communication with the second end of the liquid inlet tube, and a third condensing tube wound around an outer wall of a bottom part of the inner tank beneath the lower part. A first end of the third condensing tube may be in fluid communication with second ends of the first and second condensing tubes respectively. A second end of the third condensing tube may be in fluid communication with a first end of the liquid outlet tube. A heat pump water heater comprising the water tank may be further provided.

Abstract: A heat exchanger and a gas-fired furnace including the same are provided. The heat exchanger includes at least two heat exchange shell enclosures; and at least three rows of heat exchange tubes arranged along a furnace air flow path. Each of the heat exchange tubes defines a leaving-tube-end and an entering-tube-end, two adjacent rows are spaced from each other, the at least three rows of heat exchange tubes are connected in a leaving-tube-end to entering-tube-end fashion sequentially via the at least two heat exchange shell enclosures to define a substantially serpentine flue gas passage.