A beverage cooling device including a housing having a top wall, a side wall, and a cavity. A motor is operatively connected to a power supply within the housing. A container engagement member is rotatably coupled to the motor and configured to receive torque from the motor when the motor is actuated. The container engagement member includes an aperture for receiving an inserted beverage container and a plurality of spring members configured to deform upon insertion of the beverage container into the aperture and to provide a gripping force upon the beverage container.

A beverage cooling device including a housing having a top wall, a side wall, and a cavity. A motor is operatively connected to a power supply within the housing. A container engagement member is rotatably coupled to the motor and configured to receive torque from the motor when the motor is actuated. The container engagement member includes an aperture for receiving an inserted beverage container and a plurality of spring members configured to deform upon insertion of the beverage container into the aperture and to provide a gripping force upon the beverage container.

A beverage-dispensing appliance may include a carbonation tank, a carbonator jacket, a cold water line, and an ice bin. The carbonation tank may define a tank volume, a water inlet upstream from the tank volume, a carbon dioxide inlet upstream from the tank volume, and a carbonated water outlet downstream from the tank volume. The carbonator jacket may define a jacket volume disposed about the carbonation tank. The cold water line may extend to the carbonator jacket in upstream fluid communication with the tank volume to direct a cold water flow to the tank volume. The ice bin may be spaced apart from the carbonation tank. The ice bin may define a drain aperture upstream from the cold water line to direct melt water thereto.

A beverage-dispensing appliance may include a carbonation tank, a carbonator jacket, a cold water line, and an ice bin. The carbonation tank may define a tank volume, a water inlet upstream from the tank volume, a carbon dioxide inlet upstream from the tank volume, and a carbonated water outlet downstream from the tank volume. The carbonator jacket may define a jacket volume disposed about the carbonation tank. The cold water line may extend to the carbonator jacket in upstream fluid communication with the tank volume to direct a cold water flow to the tank volume. The ice bin may be spaced apart from the carbonation tank. The ice bin may define a drain aperture upstream from the cold water line to direct melt water thereto.

In one example, a shell includes walls that collectively define an interior space of the shell, the interior space sized and configured to receive heat generating equipment. An internal heat exchanger disposed within the interior space is arranged for thermal communication with heat generating equipment when heat generating equipment is located in the interior space. Additionally, an external heat exchanger is located outside of the shell and arranged for fluid communication with the internal heat exchanger. Finally, a prime mover is provided that is in fluid communication with the internal heat exchanger and the external heat exchanger, and the prime mover is operable to circulate a flow of coolant through the internal heat exchanger and the external heat exchanger.

In one example, a shell includes walls that collectively define an interior space of the shell, the interior space sized and configured to receive heat generating equipment. An internal heat exchanger disposed within the interior space is arranged for thermal communication with heat generating equipment when heat generating equipment is located in the interior space. Additionally, an external heat exchanger is located outside of the shell and arranged for fluid communication with the internal heat exchanger. Finally, a prime mover is provided that is in fluid communication with the internal heat exchanger and the external heat exchanger, and the prime mover is operable to circulate a flow of coolant through the internal heat exchanger and the external heat exchanger.

A portable beverage carrier and dispenser. The carrier comprises an elongate tube have one end open and the opposite end generally enclosed. The tube includes perforations to permit water to move in and out of the tube, and a float that is placed into the tube prior to inserting beverage containers. The carrier is designed to be inserted into a hole in the ice surface on a body of water. A flange prevents the tube from falling into the hole into the underlying body of water. Anchors can be provided to anchor the carrier to the ice surface. When the carrier is placed in a hole in the ice surface, water enters the interior of the tube via the perforations. The float is placed in the tube and then beverage containers are loaded on top of the float. The buoyancy of the float in the water forces the beverage containers upwards in the tube so that the topmost container can be readily retrieved by a user.

A portable beverage carrier and dispenser. The carrier comprises an elongate tube have one end open and the opposite end generally enclosed. The tube includes perforations to permit water to move in and out of the tube, and a float that is placed into the tube prior to inserting beverage containers. The carrier is designed to be inserted into a hole in the ice surface on a body of water. A flange prevents the tube from falling into the hole into the underlying body of water. Anchors can be provided to anchor the carrier to the ice surface. When the carrier is placed in a hole in the ice surface, water enters the interior of the tube via the perforations. The float is placed in the tube and then beverage containers are loaded on top of the float. The buoyancy of the float in the water forces the beverage containers upwards in the tube so that the topmost container can be readily retrieved by a user.

The present invention relates to the utilization of deep ocean seawater in cooling water for offshore process applications. The present invention contemplates extracting deep seawater from regions of the ocean having minimal biological productivity for use as cooling water in offshore operations. In one embodiment, a sea water extraction system according to the invention may include a submersible pump, a pipe and riser, a floating vessel, a transfer pipe, and a cooling water heat exchanger system.

The present invention relates to the utilization of deep ocean seawater in cooling water for offshore process applications. The present invention contemplates extracting deep seawater from regions of the ocean having minimal biological productivity for use as cooling water in offshore operations. In one embodiment, a sea water extraction system according to the invention may include a submersible pump, a pipe and riser, a floating vessel, a transfer pipe, and a cooling water heat exchanger system.