A water extractor includes an inlet, an outlet a body, outer wall, inner wall, helical wall, plurality of catchment areas, and scuppers. The body extends between the inlet and the outlet. The inner wall is disposed radially inward from the outer wall and forms a main flow channel through a portion of the body. The helical wall extends between and is connected to the outer wall and the inner wall and forms a helical passageway fluidly connected to the inlet and the outlet. The helical passageway includes a plurality of turns along a bottom of the body. One of the catchment areas is disposed in each turn of the helical passageway. The scuppers are disposed in the catchment areas and are connected to and extend radially inward from the outer wall.

A water extractor includes an inlet, an outlet a body, outer wall, inner wall, helical wall, plurality of catchment areas, and scuppers. The body extends between the inlet and the outlet. The inner wall is disposed radially inward from the outer wall and forms a main flow channel through a portion of the body. The helical wall extends between and is connected to the outer wall and the inner wall and forms a helical passageway fluidly connected to the inlet and the outlet. The helical passageway includes a plurality of turns along a bottom of the body. One of the catchment areas is disposed in each turn of the helical passageway. The scuppers are disposed in the catchment areas and are connected to and extend radially inward from the outer wall.

A refrigerant evaporator includes: a first heat exchange part in which refrigerant flows to exchange heat with fluid to be cooled; a second heat exchange part arranged to oppose the first heat exchange part; a first tank arranged below the first heat exchange part to distribute the refrigerant to the first heat exchange part; a second tank arranged below the second heat exchange part to collect the refrigerant flowing through the second heat exchange part; and a third tank joined to the first tank and the second tank by brazing. A projection part is formed at one of joint portions between the first tank and the third tank. An insertion part is formed at the other of the joint portions between the first tank and the third tank, and the projection part is inserted in the insertion part.

The invention relates to a method of cleaning the condenser coil subassembly of an air conditioning apparatus and a bag apparatus for achieving that result. The invention envisions placing a flexible bag construction over and generally around such subassembly, but not over or around the subassembly containing the other components of the air conditioner. This bag has an adjustable mouth portion that will fit over the condenser coil subassembly and also has respective hole means to allow the entry of compressed air and exit of vacuum air, respectively, to and from the enclosed area surrounding the condenser coil subassembly. When the bag is appropriately in place over the subassembly to be cleaned, compressed air is supplied to the enclosed area to loosen and remove debris from the coils while vacuum air is also supplied to remove the debris from the enclosed area to thereby resulting in a cleaning of the condenser coil subassembly without contaminating the area outside the bag.

A system and method for controlling a refrigeration system is disclosed. The system includes a cooled compartment, at least one heat source selectively activated to provide heat, at least one sensor, and a controller. The sensor detects a temperature and a relative humidity of ambient air that surrounds the cooled compartment. The controller is in communication with the at least one heat source and the at least one sensor. The controller includes logic for calculating a dew point temperature based on the temperature and the relative humidity. The controller also includes logic for selecting a region of operation based on at least one of the dew point temperature and the relative humidity, where the region of operation is representative of ambient conditions that surround the cooled compartment. The controller further includes logic for determining if the at least one heat source is activated based on the region of operation.

A system and method for controlling a refrigeration system is disclosed. The system includes a cooled compartment, at least one heat source selectively activated to provide heat, at least one sensor, and a controller. The sensor detects a temperature and a relative humidity of ambient air that surrounds the cooled compartment. The controller is in communication with the at least one heat source and the at least one sensor. The controller includes logic for calculating a dew point temperature based on the temperature and the relative humidity. The controller also includes logic for selecting a region of operation based on at least one of the dew point temperature and the relative humidity, where the region of operation is representative of ambient conditions that surround the cooled compartment. The controller further includes logic for determining if the at least one heat source is activated based on the region of operation.

Embodiments of a system to determine one or more corrective actions for one or more refrigeration units are disclosed. In one or more embodiments, the system comprises a server configured to generate a plurality of defrosting thermal models based on an analysis of a first set of data to generate a plurality of defrosting thermal models, determine, by the plurality of defrosting thermal models, one or more thermal features based on the first set of data and generate one or more behavior profiles associated with the one or more refrigeration units. The server is further configured to define a distinguished causal mapping between the one or more thermal features and the one or more behavior profiles and determine one or more corrective actions for each of the plurality of self-executing defrost failure instances associated with one or more refrigeration units based on the distinguished causal mapping.

A transcritical refrigeration system comprises at least one primary compressor configured to increase a pressure and temperature of a carbon dioxide (CO.sub.2) refrigerant to a first refrigerant temperature, at least one heat reclaim circuit downstream of the at least one primary compressor and configured to absorb at least a first amount of heat from the CO.sub.2 refrigerant to reduce the temperature of the CO.sub.2 refrigerant to a second refrigerant temperature, and at least one gas cooler assembly downstream of the at least one heat reclaim circuit. The at least one gas cooler assembly comprises at least one gas cooler-condenser comprising an inlet and an outlet, the inlet configured to receive the CO.sub.2 refrigerant at the second refrigerant temperature, at least one evaporator comprising an inlet and an outlet, the inlet fluidly connected to and downstream of the outlet of the at least one gas cooler-condenser, and an expansion valve positioned upstream of the inlet of the at least one evaporator.

A transcritical refrigeration gas cooler assembly comprises at least one gas cooler-condenser having an inlet and an outlet, the inlet configured to receive a carbon dioxide (CO.sub.2) refrigerant from a discharge line of a refrigeration system, at least one evaporator having an inlet and an outlet, the inlet fluidly connected to and downstream of the outlet of the at least one gas cooler-condenser, and an expansion valve positioned upstream of the inlet of at least one evaporator.

The present invention relates to a wet evaporation-based cold concentration system, which is mainly applied to the technical field of air conditioners, and particularly applied to the technical field of heat-source tower heat-pump air conditioners. By utilizing a wet evaporation theory, a low-temperature low-concentration anti-freezing solution is enabled to contact low-temperature air in a wet evaporator to perform the heat and mass transfer, and water in the anti-freezing solution is vaporized at a low temperature into the air, thereby obtaining the high-concentration anti-freezing solution. By reasonably utilizing the concentration pool and the storage pool, the low-concentration anti-freezing solution is separated from the high-concentration anti-freezing solution, thereby achieving a purpose of simultaneously concentrating and storing the anti-freezing solution