A lid may be for a temperature-conserving container and may include a bottom wall, a side wall formed around a perimeter of the bottom wall, and a top wall connected to the side wall. An insulative cavity may be between the top wall and the bottom wall, and the insulative cavity may be configured to reduce heat transfer through the lid. A lip may be formed around at least a portion of an outer surface of the side wall or the top wall. The lid may be configured to be slidably received in an opening of the temperature-conserving container such that at least a portion of the lip engages a top rim of the opening and forms a seal between the outer surface of the side wall and the inner surface of the opening, thereby sealing the temperature-conserving container.

A double-layer square insulated container includes a cuboid container body, which includes an inner liner and an outer shell, between which a vacuum layer is arranged. Reinforcing ribs are arranged on each of the inner liner and the outer shell and can make a surface of the square container evenly stressed during vacuumizing to avoid being crushed by suction. Reinforcing ribs are added to a surface of a mold. When the height of the reinforcing ribs is set to about 2 mm, the square surface is evenly stressed. Moreover, by repeated tests, the thickness of the inner liner and the outer shell is only about 0.5 mm, such that the weight of the square container is greatly reduced. Reinforcing ribs in different shapes are added to the periphery and bottom surface of the square container, which ensures support force of steel walls and improves the appearance.

Embodiments of the present disclosure are directed towards vacuum vessels, more specifically, embodiments are directed towards insulating devices and high insulating systems including vacuum vessels. As an example, a vacuum vessel can include a shell including a continuous surface layer with a shell locking portion, a liner including a continuous surface layer with a liner locking portion, where the liner locking portion and the shell locking portion interlock the shell and the liner and include a first sealant layer and a second sealant layer disposed along an interface between the continuous surface layer of the shell and the continuous surface layer of the liner.

Systems and methods for making an insulating container having at least one cavity in a lid insulating structure or base insulating structure and having at least one vacuum insulated panel disposed within the at least one cavity.

An insulating container having a base and a lid is provided. The lid may be rotatable about a hinge from a closed configuration to an open configuration and may be secured, via one or more latching devices, in either the closed configuration or the open configuration. In some examples, the rotatable lid may be non-destructively removable from the base. Some example arrangements include a removable lid that, when removed, may be secured to the base via an additional portion of the latching device. Additional features of the insulating container include handles that are integrally formed with the base, a recess formed in the base and housing a spigot, and/or a spigot guard.

A food storage container cooling system with a food storage container with walls, at least one wall defining an internal compartment with a top and a bottom, wherein the internal compartment is open at the top and closed at the bottom, and a reusable ice pack that is sized and shaped to fit into the compartment.

An insulated container for storing or shipping bottles includes a body and a lid. The body has a shell and an insert portion formed from an insulating material. The lid also has a shell and an insert portion formed from the insulating which meets the insert portion of the body to form cavities. The cavities include a temperature control pack cavity and four or more separate bottle storage cavities distributed around the temperature control pack cavity. Each of the bottle storage cavities is configured for receiving a bottle from among three or more different bottle types. Each of the bottle types has a different shape and/or size than each of the other bottle types. Each of the bottle storage cavities includes at least three bottle stop features on one or more internal surfaces. Each bottle stop feature is associated with a different one of the three or more bottle types.

A thermal conditioning wall panel (10) for use in a thermally insulating container comprises a panel body (22) having a channel (26) formed therein along one face thereof for receiving one or more thermal conditioning elements (12). At least one foot (32) is formed at the lower end of the body (22) for engagement within a socket provided on the thermally insulating container. The panel further comprises thermal conditioning element retaining elements (40) provided adjacent the longitudinal edges (29) of the channel (26), the retaining elements (40) projecting over a peripheral portion of the channel (26) for retaining the thermal conditioning elements (12) within the channel (26).

A portable insulated storage container includes a first divider and an insulated body. The first divider includes a first projection defining a length having a first dimension and a width having a second dimension. The insulated body has an internal cavity adapted for storing items and at least partially bounded by a bottom, a first wall, and a second wall opposite the first wall. The first wall includes a first groove adapted to receive the first projection in a first orientation. One of the first wall and the second wall includes a second groove adapted to receive the first projection in a second orientation. The first groove has a width adapted to receive the width of the first projection and the second groove has a width adapted to receive the length of the first projection.

A heat containment system is provided comprising a double wall steel insulated box, a vent system with a flame arrestor and a filter, a fire proof insulated lid with a fire proof seal and a latch, a fire proof wire way, and a built in charger stand. The system is configured to contain heat of a fire. The vent system to prevent excessive pressure inside the box. The built in charger stand holds a charger. The box contains heat of a battery fire associated with charging of a lithium battery. The box has a vent system to prevent excessive pressure inside the box from combustion gases. The vent system has a filter that removes soot from the combustion gases.