The present disclosure relates to a phase change material (PCM) composition and a process for preparation thereof, wherein said composition comprising a phase change material, glass fibers and xanthan gum. In a preferred embodiment, the phase change material is water (or ice) and the glass fibers are glass wool. The disclosure also relates to a stackable and sealable package enclosing the PCM composition. In a particular embodiment, the PCM composition is used to prepare a cold box that may be used in cold chain transportation.

A cooling system having a cooling chamber including a surface defining one or more openings. A surface is configured to hold at least one container. An access door provides access to the cooling chamber. A refrigeration system is configured to cool the cooling chamber by forcing cool airflow through the one or more openings in the surface. The airflow through each of the one or more openings may be similar.

In one general aspect, the subject matter described in this specification can be embodied in a display case door that includes an insulated panel assembly that is transparent to visible light. The door further includes a door frame extending about and secured to a peripheral edge of the insulated panel assembly, an electronic display overlaying the insulated panel assembly, and at least one display retainer secured to the door frame and having a coupling end that mates with the electronic display to releasably secure the display to the door frame.

According to an embodiment of the present invention, a method for controlling a water purifier delays the operating time of an agitator at an early stage of a current refrigerating cycle operation when a supercooled state has occurred in an immediately previous refrigerating cycle operation step.

Provided is a cold storage unit that has a high cold storage capacity, does not generate carbon dioxide, and enables recycling of the cold source. Also provided are a moving body and an ice slurry supply system. In the cold storage unit, a casing that defines a cold storage space has a heat insulating structure, a partition wall that faces the casing is provided at least at a top portion of the cold storage space, and a gap between the casing and the partition wall is filled with an ice slurry that is a mixture of brine and flake ice acquired by freezing the brine. In addition, it is possible to provide a supply port for supplying the ice slurry into the gap and a discharge port for discharging the ice slurry from the gap.

Provided is a cold storage unit that has a high cold storage capacity, does not generate carbon dioxide, and enables recycling of the cold source. Also provided are a moving body and an ice slurry supply system. In the cold storage unit, a casing that defines a cold storage space has a heat insulating structure, a partition wall that faces the casing is provided at least at a top portion of the cold storage space, and a gap between the casing and the partition wall is filled with an ice slurry that is a mixture of brine and flake ice acquired by freezing the brine. In addition, it is possible to provide a supply port for supplying the ice slurry into the gap and a discharge port for discharging the ice slurry from the gap.

A plate heat exchanger is disclosed herein. In some instances, the plate heat exchanger may be disposed in an ice bin of a beverage dispenser for cooling one or more fluids. The plate heat exchanger may include a top plate, a bottom plate, an outer boundary wall, and a fluid flow path disposed between the top plate and the bottom plate. The fluid flow path may include an inlet and an outlet. A fin may be disposed within the fluid flow path from the top plate to the bottom plate between the inlet and the outlet.

A plate heat exchanger is disclosed herein. In some instances, the plate heat exchanger may be disposed in an ice bin of a beverage dispenser for cooling one or more fluids. The plate heat exchanger may include a top plate, a bottom plate, an outer boundary wall, and a fluid flow path disposed between the top plate and the bottom plate. The fluid flow path may include an inlet and an outlet. A fin may be disposed within the fluid flow path from the top plate to the bottom plate between the inlet and the outlet.

A beverage diluting and cooling container includes a floor, a peripheral sidewall, and a divider wall that divides an interior space defined by the peripheral sidewall into a first compartment that receives a cooling medium for cooling and diluting a beverage received into the first compartment. The divider wall also divides the interior space into a second compartment that holds a second quantity of a cooling medium for non-dilutingly cooling the beverage. The second compartment is sealed from the first compartment to prevent flow of liquid from the second compartment into the first compartment. One or more of the floor or a portion of the sidewall bounding the first compartment includes at least one opening therethrough to allow flow of the beverage out of the first compartment while containing the cooling medium in the first compartment.

A beverage diluting and cooling container includes a floor, a peripheral sidewall, and a divider wall that divides an interior space defined by the peripheral sidewall into a first compartment that receives a cooling medium for cooling and diluting a beverage received into the first compartment. The divider wall also divides the interior space into a second compartment that holds a second quantity of a cooling medium for non-dilutingly cooling the beverage. The second compartment is sealed from the first compartment to prevent flow of liquid from the second compartment into the first compartment. One or more of the floor or a portion of the sidewall bounding the first compartment includes at least one opening therethrough to allow flow of the beverage out of the first compartment while containing the cooling medium in the first compartment.