A portable temperature-stable storage device configured to enable transport of a plurality of temperature-sensitive objects at a stable temperature, the portable temperature-stable storage device comprising: an insulating enclosure for storing the plurality of temperature-sensitive objects; an aperture in a wall of the insulating enclosure; a first barrier disposed across the aperture and configured to be moved between an open configuration and a closed configuration; a plurality of compartments for storing the plurality of temperature-sensitive objects, the plurality of compartments being comprised within the insulating enclosure, the plurality of compartments being configured to move relative to the aperture; and means for moving the compartments in turn into alignment with the aperture while the first barrier is in the closed configuration.

A multiple temperature storage assembly includes a sleeve that has an opening therein for accessing an interior of the sleeve and to receive food items for storage. The sleeve is comprised of a thermally insulating material to retain the food items at a selected temperature. A door is hingedly coupled to the sleeve for opening and closing the opening. A disk is slidably positioned within the sleeve such that the disk defines an upper section of the sleeve and a lower section of the sleeve. The disk is comprised of a thermally insulating material to inhibit thermal communication between the upper and lower sections. Thus, each of the upper and lower sections can store a respective one of warm food items and cold food items. A tube is slidably coupled to the sleeve. The tube has a chamber therein that is fluidly discrete from the sleeve when the tube is slidably coupled to the sleeve for storing dry objects.

An insulating device can include an aperture having a waterproof closure which allows access to the chamber within the insulating device. The closure can help prevent any fluid leakage into and out of the insulating device if the insulating device is overturned or in any configuration other than upright. The closure also prevents any fluid from permeating into the chamber if the insulating device is exposed to precipitation, other fluid, or submersed under water. This construction results in an insulating chamber impervious to water and other liquids when the closure is sealed.

A receiving sheath for a thermal insulating insert includes a first receiving space, e.g., for consumer goods, between a front inner wall and a rear inner wall and is limited by the same, and a second receiving space for a thermal insulating insert that surrounds the first receiving space in the direction of a bottom end and is limited in a first portion by a front outer wall and the front inner wall. The present disclosure also relates to a multi-chamber insulated pocket with the receiving sheath and a use of said receiving sheath.

Described in detail herein is cooler apparatus. The cooler can include an outer shell and an inner shell. The outer shell can include a top face, a bottom face, a front surface, back surface a first side and a second side. The top face can be secured to the cooler using a zipper. The top face can provide access the inner shell. One or more bottle openers can be affixed to the front surface of the outer shell. The front surface can further include an enclosure accessible using a zipper. The bottom side can be compressible in response to receiving pressure. One or more straps can be affixed to either the first side, second side or back surface of the cooler. The inner shell can form a volume to store physical objects. The cooler can be a backpack, tote or a 24-pack cooler.

An insulating device can include an aperture having a waterproof closure which allows access to the chamber within the insulating device. The closure can help prevent any fluid leakage into and out of the insulating device if the insulating device is overturned or in any configuration other than upright. The closure may also prevent any fluid from permeating into the chamber if the insulating device is exposed to precipitation, other fluid, or submersed under water. This construction results in an insulating chamber that is substantially impervious to water and other liquids when the closure is sealed.

The present application generally relates to devices and methods for transporting, delivering, and storing items, and it more specifically relates to insulated carriers for use in transporting, delivering, and storing temperature controlled items such as perishable food and beverage items. The containers are collapsible and insulated to allow for the efficient storage and transport of the containers while empty.

A container assembly has a soft-sided insulated wall structure. It has an internal chamber in which to place objects, such as foodstuffs, to be kept cool or warm. There is a first closure member that opens and closes to permit objects to be place in, or removed from, the chamber. The wall structure includes one or more accommodations in which to place a warming or cooling element, such as an ice pack. The accommodations are externally accessible without opening the main chamber, and have their own closure. The outside of the accommodation may be insulated; the inside is a thin web through which to transfer heat. The container may be a collapsible foldable bag; a tote bag; back pack or a non-collapsible lunch box. The thermal storage elements may have a flat disk shape. The external access for the thermal storage elements permits them to slide sideways into place.

A novel refrigeration and insulation bag includes a bag body and a top cover. An interior of the bag body forms a cavity, and a top end of the bag body is provided with an opening. The top cover is used for closing the opening, an interior of the top cover forms an accommodating cavity, and a refrigeration assembly or a refrigeration/heating assembly is embedded in the accommodating cavity. The refrigeration assembly or refrigeration/heating assembly includes semiconductor chilling plates, heat dissipation fans, temperature-uniforming plate, power supply component, and other components. The refrigeration assembly or refrigeration/heating assembly of the present disclosure powered by electricity is configured to refrigerate the interior of the bag, so as to create a low-temperature environment without the need to frequently replace the ice packs before use, or configured to heat up the interior of the bag, so as to keep warm of the bag.

A wine dispenser that includes a wine refrigerator unit having a compartment with a support to support a wine container, and a wine dispenser unit residing atop the wine refrigeration unit, the wine dispenser unit including a plurality of fountain heads, each one of the plurality of fountain heads being connected to a respective fluid-tight wine supply line that extends from the fountain head to an interior of the compartment.