A container assembly comprises a V-shaped container having a V-shaped cross-section and being formed from freezer-safe material, and a support base having a V-shaped groove sized to received and cooperate with the container thereby to support the container during filling with freezable liquid. Also disclosed is a freezer container support structure comprising two or more plates and at least two spaced support members. The support members are adapted to engage the plates in spaced locations along the support members, to maintain one or more freezer containers between the plates during freezing of a freezable liquid contained in each said freezer container.

An enclosure includes a shell including a movable cover, a cavity defined by a plurality of walls extending from a base, and a closure that removably attaches the movable cover to one or more walls of the plurality of walls. The enclosure further includes a pocket assembly that includes a pocket having a folding region disposed at least partially between opposing side edges and a backing panel. The folding region has a closure mechanism for retaining the pocket against itself in a collapsed configuration. Further, the backing panel is coupled to the shell and the pocket is configured to receive a beverage container when placed in the open configuration.

An insulating device may include a body comprising an outer shell, an insulating layer and aerogel structure adjacent to the outer shell, and an inner liner secured to the outer shell. The aerogel structure may comprise skiving features that extend from a surface of the aerogel structure to a mid-point width of the aerogel structure and may be configured to facilitate folding of the aerogel structure.

An insulating device can include a body assembly and a lid assembly where an insulating layer and aerogel structure is connected to both the body assembly and the lid assembly. An aperture with a closure is formed between the body assembly and lid assembly to form a storage compartment. The insulating layer and aerogel structure on the lid assembly may extend beyond the closure when the closure is sealed. The insulating layer and aerogel structure on the lid assembly may have an insulating ring and aerogel ring structure that has an increased thickness around its perimeter.

An insulating device backpack may include an outer shell, a first sidewall defining a front portion of the insulating device backpack, and a second sidewall and a third sidewall defining side portions of the insulating device backpack, and a fourth sidewall defining a back portion of the insulating device backpack, an inner liner forming a storage compartment, an insulating layer positioned in between the outer shell and the inner liner, the insulating layer providing insulation for the storage compartment, and an opening configured to allow access to the storage compartment, and a closure adapted to seal the opening.

The thermal bag (2) is made of thermally insulating composite material folded to form a bottom and welded along lateral borders (3) to form a body (1) of the bag with a mouth (5) at the level of which a handle (7A, 7B) is applied. The composite material defines a bottom folded in an accordion-like fashion opposite the mouth of the bag, and a laminar stiffening element (15) of the accordion-like bottom is disposed inside the bag.

An ice bagging assembly and related method with a horizontal ice bag cassette, a pair of opposing ice bag ply graspers configured to move an empty ice bag from the horizontal ice bag cassette to a vertical position to receive cubed ice before it is sealed shut and dropped to an ice bag merchandiser. The opposing graspers may be configured as rotating wheels and may have a grasping sensor. The ice bag cassette may be slidably and tiltably supported for easy replacement of horizontal bags. A load sensor, optical or mechanical, may be associated with the ice hopper to sense how much ice has been put in each bag. A pair of angled guides may guide a hopper into a support frame for the system.

A container assembly has a soft-sided insulated wall structure. It has one or more internal chambers in which to place objects to be kept cool or warm. A first closure member governs access to the container assembly. The wall structure includes one or more accommodations in which to place a warming or cooling element, such as an ice pack. The accommodations in the outside walls are externally accessible without opening the main chamber, and have their own closure, and may be insulated. The inside is a thin web through which to transfer heat. An internal partition divides the container assembly into two chambers. The partition may have a thermal storage element. 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 disks slide sideways into place in the respective accommodations.

Thermal protection for sensitive items stored for extended periods of time in a passenger vehicle is a requirement that has not been adequately addressed by the industry. A primary object of this invention therefore, will be to provide a convenient and versatile means for forming and integrating a storage container employing appropriate phase change materials to create a controlled temperature environment for heat-sensitive articles inside an automobile, truck, or other enclosed road vehicle. As such, the invention will afford protection where summer temperatures build up to levels inside the stationary vehicle which could exceed safe limits for heat sensitive items that might be stored in the vehicle for an extended period of time; ie an hour or more. An additional optional objective will be to further include a phase change material with a substantially lower melting point to protect sensitive items from freezing during the winter months.

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.