A refrigerator including a refrigerator compartment, a freezer compartment, an ice maker compartment, a machine compartment, a first evaporator, a second evaporator, and a pressure balancing conduit. The ice maker compartment is configured to store ice and receive air from the freezer compartment. The machine compartment is located outside the freezer and ice maker compartments and houses one or more of a compressor, a condenser, a fan, or a coolant tank. The first evaporator is configured to cool air within the refrigerator compartment. The second evaporator is configured to cool air within the freezer compartment. The pressure balancing conduit is configured to balance air pressure within the freezer compartment.

A vacuum insulated door for an appliance includes an outer wrapper that defines an evacuation port. An inner liner is coupled to the outer wrapper defining an insulating cavity therebetween. A base is coupled to the outer wrapper adjacent to the evacuation port. A servicing tube has a connecting end and a servicing end. The servicing tube is in fluid communication with the insulating cavity via the evacuation port. The connecting end is coupled to the base. A handle has first and second ends coupled to the outer wrapper and a center portion therebetween spaced-apart from the outer wrapper. The first end is coupled to the outer wrapper proximate the evacuation port. The servicing tube extends along an inner surface of the handle.

A hard-sided cooler box may include a channel or cylindrical-shaped hole that extends from the outside of the cooler box to the inside of the cooler box. This cylindrical-shaped hole or channel may be covered/sealed by one or more latches of the cooler box when the cooler box is closed, and the latches are secured. However, when the latches of the cooler box are released, the cylindrical-shaped hole or channel may be unblocked, and the air from the interior of the cooler box can escape to the outside of the cooler box before the lid is lifted from the body. This allows the lid to be opened with no struggle.

The present invention is directed to a system (100) maintaining chilled temperature in a cold storage (102) comprising: a plurality of coolant layers 104 uniformly placed on the roof of said storage (102); each coolant layer comprising multiple coolant plates (106) stacked in rows and columns; a compressor (110) generating airflow and circulating airflow in a circular pattern from top to bottom in said (storage 102); thereby maintaining temperatures in the range −25° C. to +25° C. in said storage; said plurality of coolant layers (104) being placed in close proximity to said compressor (110) for effectively circulating airflow; a coolant holder frame (108) for uniformly adjusting said multiple coolant plates (106) in said plurality of coolant layers (104), and allowing efficient airflow from top to bottom in said storage (102); base of said storage being provided with, holes (112), throughout for sucking the air circulated by said compressor (110) to improve the circulation of airflow in said storage (102); and said storage (102) being insulated to increase the thermal insulation coefficient to maintain the desired temperature in said storage, thereby freezing said coolant layers.

A refrigerator includes a drain assembly guiding water downward into a water container. The drain assembly includes a drain valve having a valve body, a water inlet and a drain outlet. The water inlet conducts water into, and the drain outlet conducts water out of, the valve body. A water passage between water inlet and drain outlet includes first and second side by side cavities. The drain valve includes a water valve isolating the first cavity from the second cavity or communicating the first and second cavities. The configuration of the water passage and water valve allows the height of the drain assembly to be lowered. During manufacture and assembly of the refrigerator, interference and restriction of the drain assembly upon mounting and assembly of other components are reduced. Gravity of the water valve has less impact on sensitivity of the water valve, and the drain assembly is more sensitive.

A ventilation unit for a low temperature chamber with a tube-shaped base body, having a heating element, an inlet side end with an inlet opening and an outlet side end with an outlet opening, wherein the base body has a tapered form such that the inlet opening has a greater area than the outlet opening. The inlet opening can be located in a first front side plane and the outlet opening can be located in a second front side plane, wherein the first front side plane and the second front side plane are substantially parallel offset with respect to one another, and wherein at perpendicular projection of the first front side plane onto the second front side plane, the inlet opening and the outlet opening are disposed offset with respect to one another. The base body can have a mechanical valve configured to open under pressure induction.

A jumper drain for a refrigerator appliance, the jumper drain including a housing with a cavity defined therein and that is in fluid communication with a storage compartment of the refrigerator appliance. An inlet and an outlet extend from the housing and are both in fluid communication with the cavity. The outlet is disposed at a location that is offset from the inlet. A pressure equalizer opening is formed in the housing. The pressure equalizer opening is configured to provide fluid communication between the cavity and an ambient environment external to the refrigerator appliance in order to equalize a pressure differential within the refrigerator appliance.

A refrigerated display cabinet (10) includes a refrigeration loop including a compressor, a condenser, a throttling element and an evaporator which are connected; a main body (12) including a storage space (14), wherein the evaporator (16) is located within the main body and is for supplying cooling to the storage space (14); and a container (18) located outside of the storage space (12) and containing at least one of the compressor, condenser and throttling element, wherein the container (18) comprises a vent (20) configured to discharge any build-up of gases within the container (18) outwardly.

A drain extension assembly for an appliance that provides fluid communication between an internal storage compartment and an exterior environment via an appliance drain that collects and transfers liquid condensate from an evaporator. The drain extension assembly includes a main body with an inlet and an outlet. The inlet is configured to be secured to the appliance drain and the outlet is configured to be secured to an extension tube discharges the liquid condensate into a drain pan. A vacuum relief system provides selective fluid communication between the main body and the exterior environment. The vacuum relief system includes a pressure relief valve provided at a wall of the main body.

Delivering items to users by a delivery organization comprises a delivery container suitable to deliver items that require storage at a specific temperature range for the duration of the delivery. The delivery container may be a cube or a rectangular prism constructed of an insulating material. The delivery organization may position a panel in the delivery container to separate a chilled compartment from a compartment with a coolant. The panel between the compartments includes a pressure relief valve that opens when the pressure difference between the compartments reaches a set point. The open valve allows the chilled compartment to exchange air with the compartment with the coolant until the drop in the pressure difference allows the valve to close. The temperature in the chilled compartment is maintained in the desired range by the opening and closing of the valve.