A method of thermally conditioning a physical object, includes guiding a two-phase cooling medium through a cooling duct of the physical object, wherein the guiding includes: guiding the two-phase cooling medium in a liquid phase via a pre-heating duct of the physical object from a supply side of the physical object at least partly towards a discharging side of the physical object, the two-phase cooling medium being pre-heated in the pre-heating duct; guiding the two-phase cooling medium from the pre-heating duct to a phase transitioning duct of the physical object, the two-phase cooling medium at least partly transitioning from the liquid phase towards a gas phase in the phase transitioning duct; guiding the two-phase cooling medium from the phase transitioning duct to a discharging duct of the physical object; and discharging at the discharging side the two-phase cooling medium from the discharging duct.

An ice maker evaporator assembly having an evaporator pan with a back wall and left, right, top and bottom sidewalls extending from the back wall, and a freeze plate located within the evaporator pan. Refrigerant tubing is thermally coupled to the back wall of the evaporator pan opposite the left, right, top and bottom sidewalls. A first layer of insulation is formed on the refrigerant tubing. An evaporator housing having a housing back wall and housing left, right, top and bottom sidewalls extending from the housing back wall is attached to the evaporator pan and covers refrigerant tubing. A second layer of insulation is formed on top of the first layer of insulation.

Disclosed is a refrigerator. First and second inner containers (110, 120) are respectively provided with first and second tube evaporators (210) in the inside thereof. The first and second inner containers (110, 120) are respectively provided with first and second winding tube evaporators (310, 320) on the outside thereof. First connecting tubes protrude from the first inner container (110) at two ends of the first tube evaporator (210), and the first winding tube evaporator (310) is connected to one of the first connecting tubes. Second connecting tubes protrude from the second inner container (120) at two ends of the second tube evaporator, the second winding tube evaporator (320) is connected to one of the second connecting tubes, and the other of the first connecting tubes is connected to the other of the second connecting tubes.

An ice maker evaporator assembly having an evaporator pan with a back wall and left, right, top and bottom sidewalls extending from the back wall, and a freeze plate located within the evaporator pan. A serpentine tubing is thermally coupled to the back wall of the evaporator pan opposite the left, right, top and bottom sidewalls. A first layer of insulation is formed on the serpentine tubing. An evaporator housing having a housing back wall and housing left, right, top and bottom sidewalls extending from the housing back wall is attached to the evaporator pan and covers serpentine tubing. A second layer of insulation is formed on top of the first layer of insulation.

A method of thermally conditioning a physical object, includes guiding a two-phase cooling medium through a cooling duct of the physical object, wherein the guiding includes: guiding the two-phase cooling medium in a liquid phase via a pre-heating duct of the physical object from a supply side of the physical object at least partly towards a discharging side of the physical object, the two-phase cooling medium being pre-heated in the pre-heating duct; guiding the two-phase cooling medium from the pre-heating duct to a phase transitioning duct of the physical object, the two-phase cooling medium at least partly transitioning from the liquid phase towards a gas phase in the phase transitioning duct; guiding the two-phase cooling medium from the phase transitioning duct to a discharging duct of the physical object; and discharging at the discharging side the two-phase cooling medium from the discharging duct.

An ice maker evaporator assembly having an evaporator pan with a back wall and left, right, top and bottom sidewalls extending from the back wall, and a freeze plate located within the evaporator pan. Refrigerant tubing is thermally coupled to the back wall of the evaporator pan opposite the left, right, top and bottom sidewalls. A first layer of insulation is formed on the refrigerant tubing. An evaporator housing having a housing back wall and housing left, right, top and bottom sidewalls extending from the housing back wall is attached to the evaporator pan and covers refrigerant tubing. A second layer of insulation is formed on top of the first layer of insulation.

An ice making machine having a refrigeration system designed for hydrocarbon (HC) refrigerants, and particularly propane (R-290), that includes dual independent refrigeration systems and a unique evaporator assembly comprising of a single freeze plate attached to two cooling circuits. The serpentines are designed in an advantageous pattern that promotes efficiency by ensuring the even bridging of ice during freezing and minimizing unwanted melting during harvest by providing an even distribution of the heat load. The charge limitations imposed with flammable refrigerants would otherwise prevent large capacity ice maker from being properly charged with a single circuit. The ice making machine includes a single water circuit and control system to ensure the proper and efficient production of ice. Material cost is conserved as compared to a traditional dual system icemaker.

A heat exchanger module includes a skin condenser and a skin evaporator. The skin condenser includes an inner condenser plate, an outer condenser plate coupled to the inner condenser plate and a condenser tube channel formed on one of the inner condenser plate and/or the outer condenser plate. The evaporator includes an inner evaporator plate, an outer evaporator plate coupled to the inner evaporator plate, and an evaporator tube channel formed on one of the inner evaporator plate and/or the outer evaporator plate. The heat exchanger also includes an insulation layer extending between the inner condenser plate and the inner evaporator plate. Each of the plates that form the skin condenser and/or evaporator can be formed from different materials and/or have different material thicknesses to reduce heat transfer through the insulation layer from the condenser to the evaporator while also promoting heat transfer through natural convection with surrounding air.