An apparatus for delivering circulating water includes a cooling/warming controller configured to perform heat exchange of circulating water supplied to a cooling/warming apparatus using a refrigerant; an indoor-unit controller configured to perform heat exchange of circulating water supplied to an indoor unit using the refrigerant; and a mode change unit (MCU) configured to control a flow of the refrigerant supplied to the cooling/warming controller and the indoor-unit controller according to an operation mode of the cooling/warming apparatus and the indoor unit. The cooling/warming controller and the indoor-unit controller may be configured to share a circulating water passage through which the circulating water moves.

An outdoor unit (100) for an air conditioner and the air conditioner are disclosed. The outdoor unit (100) for the air conditioner includes: a housing (1), a FREON charging nozzle (14), and a connector assembly. The FREON charging nozzle (14) is disposed in the housing (1); the connector assembly has a first end connected to the FREON charging nozzle (14) and a second end extending out of the housing (1).

The present invention relates to an air conditioner. The air conditioner according to the present embodiment has a refrigeration capacity of 11 kW to 16 kW, inclusive, and uses R134a as a refrigerant circulating therein, and since a refrigerant pipe therein is made of a ductile stainless steel material having 1% or less of a delta-ferrite matrix structure with respect to the grain size area thereof, the refrigerant pipe can maintain strength and hardness as good as or better than those of a copper pipe, while also maintaining good processability.

The present invention relates to an air conditioner. The air conditioner according to the present embodiment has a refrigeration capacity of 11 kW to 16 kW, inclusive, and uses R134a as a refrigerant circulating therein, and since a refrigerant pipe therein is made of a ductile stainless steel material having 1% or less of a delta-ferrite matrix structure with respect to the grain size area thereof, the refrigerant pipe can maintain strength and hardness as good as or better than those of a copper pipe, while also maintaining good processability.

Disclosed herein are an air conditioner system and a controlling method thereof. In a situation that air-conditioning systems such as air conditioners and refrigerators are installed and operated in a site, real-time operation data are acquired and the air conditioning and efficiency are calculated at the site. By comparing performance data provided by a device manufacturer and the real-time operation data, device performance is corrected for the site's installation environment. By using corrected device performance, it is possible to save building facility energy by providing optimal operation number control suitable for the installation environment.

Disclosed herein are an air conditioner system and a controlling method thereof. In a situation that air-conditioning systems such as air conditioners and refrigerators are installed and operated in a site, real-time operation data are acquired and the air conditioning and efficiency are calculated at the site. By comparing performance data provided by a device manufacturer and the real-time operation data, device performance is corrected for the site's installation environment. By using corrected device performance, it is possible to save building facility energy by providing optimal operation number control suitable for the installation environment.

A heat exchange unit includes a heat exchanger, a structure supporting the heat exchanger, an insulating member electrically insulating the heat exchanger from the structure, a compressor electrically connected to the heat exchanger and the structure, and a connection member attached to the heat exchanger. The connection member electrically connects the heat exchanger and the structure. The connection member is provided separately from a first conductive path that electrically connects the compressor and the heat exchanger, and a second conductive path that electrically connects the compressor and the structure.

The present invention is a device for providing a non-conductive refrigerant line break that provides an electrical discontinuity in a high-pressure metallic refrigerant line. The present invention could be used for the installation of HVAC units in which metallic refrigerant lines would necessarily penetrate a security partition or security wall. In an embodiment, a conductive line run external to a secure facility would be broken by a non-conductive line approximately contemporaneously with the conductive line's wall penetration or entirely within an internal cavity. The non-conductive line would run a distance determined by a consulting engineer to provide sufficient security given the application. The non-conductive line would then be attached to a conductive line within the secure facility. The present invention utilizes a non-threaded fitting extension to increase surface area for epoxy bonding.

An outdoor system for an air conditioner may include at least one outdoor unit, the at least one outdoor unit including a compressor; an outdoor heat exchanger; a pair of two-stage compression lines that extends to outside of the outdoor system; a pair of connection lines that extends to the outside of the outdoor system and communicates with an indoor unit; and multiple valves that open/close the pair of two-stage compression lines and the pair of connection lines when the outdoor system is operated in a one-stage heating mode or a two-stage heating mode.

A heating, ventilation, and/or air conditioning (HVAC) packaged unit includes a first refrigerant circuit component configured to change a temperature or a pressure of a refrigerant flowing through the first refrigerant circuit component and a second refrigerant circuit component configured to change a temperature or a pressure of the refrigerant flowing through the second refrigerant circuit component. The first and the second refrigerant circuit components are within a common refrigerant circuit that is disposed within a common support structure. The HVAC packaged unit also includes an interconnection conduit having a length formed from aluminum, a first end segment coupled to a first end of the length, and a second end segment coupled to a second end of the length. The first end segment and the second end segment are each formed from copper, and the interconnection conduit extends between the first refrigerant circuit component and the second refrigerant circuit component.