A household cooling appliance has a housing with a receiving space for food, a door for closing the receiving space, wherein the door is movably arranged at the housing, an ice maker with an ice tray, wherein the ice maker with the ice tray is arranged in the door, a first cooling device, which is arranged at the door and by which the ice tray is cooled, wherein the first cooling device comprises a waste heat unit by which the waste heat resulting from the cooling of the ice tray can be dissipated, and a second cooling device, which is arranged at the housing and by which the receiving space is cooled. The waste heat unit of the first cooling device is thermally coupled with the second cooling device such that the waste heat of the waste heat unit can be transferred to the second cooling device.

A refrigerator includes a storage space defined in a cabinet and a machine room arranged under the storage space. To implement a cooling system, a compressor, a condenser, and a heat dissipation fan are included in the machine room. In addition, a control module is provided in the machine room to face an outlet of the machine room. The control module is installed at a position close to the entrance of the machine room and configured to be separated frontward from the machine room, and thus accessibility to the control module can be enhanced.

A refrigerated device is configured to enhance condensate evaporation and includes a compartment including an access door, a refrigeration circuit for cooling the compartment, the refrigeration circuit including an evaporator coil and a condenser with an associated condenser fan, and a condensate pan for capturing condensate from the evaporator coil. At least one first air flow path is provided from a pressure side of the condenser fan, into and along at least part of the condensate pan and then to a suction side of the condenser fan. At least one second air flow path is provided from the pressure side of the condenser fan, into and along at least part the condensate pan and then back to the pressure side of the condenser fan.

An evaporative condensate dissipation system includes a receptacle configured to receive and accumulate a liquid condensate from a cooling element of a refrigeration system, a rotating element (e.g., an array of plates, a rotating drum, etc.) disposed at least partially within the receptacle such that a portion of the rotating element is submerged in the liquid condensate, and a motor configured to cause the rotating element to rotate such that a portion of the rotating element is periodically submerged in the liquid condensate and emerged from the liquid condensate. A fan may be used to provide an airflow across a surface of the rotating element to increase expedite evaporative dissipation. The fan and/or motor may be operably controlled by a switch or sensor responsive to a level of the liquid condensate accumulated in the receptacle.

The present invention relates to a cooling and/or a freezing device comprising a cooled inner chamber (100) and a thermoelectric element (20), particularly a Peltier element (20), which is arranged such that the inner chamber (100) is cooled by means of the thermoelectric element (20), means (4, 20, 40) for evaporating the condensed water being provided comprising a heat exchanger (40) located outside of the cooled inner chamber (100).