An ice luge mould (1), the mould (1) comprising a first part (2) and a complementary second part (3), the first part (2) and the second part (3) being configured to form an internal cavity therebetween when assembled, the mould (1) further comprising a water inlet (20) and a fluid-tight seal (21, 31) provided around the periphery of the first part (2) and second part (3) and a channel-forming means (32) configured to form a channel in the ice luge.

An ice luge mould (1), the mould (1) comprising a first part (2) and a complementary second part (3), the first part (2) and the second part (3) being configured to form an internal cavity therebetween when assembled, the mould (1) further comprising a water inlet (20) and a fluid-tight seal (21, 31) provided around the periphery of the first part (2) and second part (3) and a channel-forming means (32) configured to form a channel in the ice luge.

Disclosed is a system and method for cleaning an ice machine, a cleaning apparatus comprising an ozone generator, at least one fluid line connecting an output from the ozone generator to at least one of a water inlet, a water recirculatory line, and a water reservoir, wherein the cleaning apparatus is configured for use with an ice machine. In some embodiments, one or more sensors are provided and may be configured to detect a call for new ice formation. The one or more sensors may comprise (i) a flow valve sensor, (ii) a sensor configured to detect if water is flowing through a water inlet, (iii) a sensor configured to detect a beginning of new ice formation, and/or (iv) a sensor configured to detect an end of new ice formation.

Disclosed is a system and method for cleaning an ice machine, a cleaning apparatus comprising an ozone generator, at least one fluid line connecting an output from the ozone generator to at least one of a water inlet, a water recirculatory line, and a water reservoir, wherein the cleaning apparatus is configured for use with an ice machine. In some embodiments, one or more sensors are provided and may be configured to detect a call for new ice formation. The one or more sensors may comprise (i) a flow valve sensor, (ii) a sensor configured to detect if water is flowing through a water inlet, (iii) a sensor configured to detect a beginning of new ice formation, and/or (iv) a sensor configured to detect an end of new ice formation.

An ice machine includes a plurality of cooling tubes with each cooling tube having an inner tube and an outer tube extending around the inner tube to define an annular cavity between the inner tube and the outer tube. When refrigerant flows through the annular cavity between the inner tube and the outer tube, water in the inner tube freezes. The ice machine may also include a shell defining an internal cavity through which the plurality of cooling tubes extend; a water source operably connected to a water pump to flow water through the inner tube; a refrigerant source operably connected to a refrigerant pump to flow refrigerant through the annular cavity; and a heater operably connected to the internal cavity of the shell to flow a heated fluid through the internal cavity and across the plurality of cooling tubes.

A cross-connected refrigeration system includes a first refrigeration subsystem and a second refrigeration subsystem that are fluidly coupled by a header, each of the first refrigeration subsystem and the second refrigeration subsystem including a refrigeration loop including a compressor, a condenser, an expansion device, and an evaporator, and a heating loop including an electrically-controlled valve, and the evaporator, and a header connection that connects the refrigeration loops and the heating loops of the first refrigeration subsystem and the second refrigeration subsystem to a common header, respectively. The compressor in the first refrigeration subsystem is selectively deactivated and the electrically-controlled valve in the first refrigeration subsystem is selectively opened such that compressed gas from the compressor in the second refrigeration subsystem enters the heating loop of the first refrigeration subsystem and heats the evaporator of the first refrigeration subsystem.

A bottle with an ice cube mould, comprises a bottle body (1) with a neck (111) and a lid (2), the bottle body (1) has two ice-making plates (3) opposite with each other, at least one of the two ice-making plates (3) has a plurality of recesses (31), and the two ice-making plates (3) are capable of moving relative to each other; when the two ice-making plates (3) are at the closed state, two recesses facing each other (31) form an ice-making space, and a water flow channel for guiding water coming from the water inlet (32) to the ice-making space is formed between the two ice-making plates (3); when the two ice-making plates (3) are at the opened state, a chamber (A) of the bottle body (1) is defined between the two ice-making plates (3), and ice cubes formed inside the recesses drop into the chamber (A) of the bottle body (1). The bottle has both an ice-making function and a water-containing function, and it is sanitary to make ice cubes and also convenient to take the ice cubes out.

A bottle with an ice cube mould, comprises a bottle body (1) with a neck (111) and a lid (2), the bottle body (1) has two ice-making plates (3) opposite with each other, at least one of the two ice-making plates (3) has a plurality of recesses (31), and the two ice-making plates (3) are capable of moving relative to each other; when the two ice-making plates (3) are at the closed state, two recesses facing each other (31) form an ice-making space, and a water flow channel for guiding water coming from the water inlet (32) to the ice-making space is formed between the two ice-making plates (3); when the two ice-making plates (3) are at the opened state, a chamber (A) of the bottle body (1) is defined between the two ice-making plates (3), and ice cubes formed inside the recesses drop into the chamber (A) of the bottle body (1). The bottle has both an ice-making function and a water-containing function, and it is sanitary to make ice cubes and also convenient to take the ice cubes out.

A cross-connected refrigeration system includes a first refrigeration subsystem and a second refrigeration subsystem that are fluidly coupled by a header, each of the first refrigeration subsystem and the second refrigeration subsystem including a refrigeration loop including a compressor, a condenser, an expansion device, and an evaporator, and a heating loop including an electrically-controlled valve, and the evaporator, and a header connection that connects the refrigeration loops and the heating loops of the first refrigeration subsystem and the second refrigeration subsystem to a common header, respectively. The compressor in the first refrigeration subsystem is selectively deactivated and the electrically-controlled valve in the first refrigeration subsystem is selectively opened such that compressed gas from the compressor in the second refrigeration subsystem enters the heating loop of the first refrigeration subsystem and heats the evaporator of the first refrigeration subsystem.

Device and method for making ice cubes, comprising a supplying device for supplying a liquid substance to at least one elongated mould (1) and a refrigerating device for freezing said liquid substance, which at least one mould defines a space for an ice column which is at least substantially closed at least while said liquid substance is being refrigerated. The at least one mould comprises two mould halves (1a, 1b) which are movable relative to each other, so that the mould halves can be moved apart once the ice column has been formed. Method for making ice cubes, comprising the steps of a) supplying a liquid substance to a mould, b) freezing the liquid substance in the mould, and c) removing the ice cubes thus formed from the mould, wherein the liquid substance is supplied in step a) to a mould comprising an at least substantially closed space. Metering device for ice cubes.