The present disclosure provides insulated components that include corrugated regions, which corrugated regions may reside on inner tubes, outer tubes, or both. The present disclosure also provides insulated components that may achieve straight, curved, or other variable geometries.

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.

An insulating container can be configured to retain a volume of liquid, and include a first inner wall having a first end having an opening extending into an internal reservoir, and a second outer wall forming an outer shell. The second outer wall can include a second end configured to support the container on a surface. The second outer wall can include a dimple, and the dimple can include a circular base and an inner portion converging to an hole extending into the second outer wall. The hole can be sealed by a resin, and the circular base can be covered by disc formed of the material. Alternatively, a cap can cover the dimple, and a weld can connect the cap to the second outer wall. The container can also include a sealed vacuum cavity forming an insulated double-wall structure between the first inner wall and the second outer wall.

An insulating container can be configured to retain a volume of liquid, and include a first inner wall having a first end having an opening extending into an internal reservoir, and a second outer wall forming an outer shell. The second outer wall can include a second end configured to support the container on a surface. The second outer wall can include a dimple, and the dimple can include a circular base and an inner portion converging to an hole extending into the second outer wall. The hole can be sealed by a resin, and the circular base can be covered by disc formed of the material. Alternatively, a cap can cover the dimple, and a weld can connect the cap to the second outer wall. The container can also include a sealed vacuum cavity forming an insulated double-wall structure between the first inner wall and the second outer wall.

The disclosure includes an insulated container for beverages and the like. The container includes a double-walled vacuum vessel with a handle and an offset dispensing opening at the top of the vessel. The opening is sealable with a cap. A tether can be provided to secure the cap to the handle.

The present invention discloses a locking device for replacing a liner in a thermos. The locking device locks and positions a liner stably by a high-pressure assembling force resulted from an elastic effect, after replacing and assembling the liner in a drinking container. A tightening ring with an elastic force is utilized primarily. The tightening ring is clamped between a mineral liner and a barrel by filling, forming a strong elastic reaction force to press and lock the elements, through a spinning action of a connecting ring.

The present invention discloses a locking device for replacing a liner in a thermos. The locking device locks and positions a liner stably by a high-pressure assembling force resulted from an elastic effect, after replacing and assembling the liner in a drinking container. A tightening ring with an elastic force is utilized primarily. The tightening ring is clamped between a mineral liner and a barrel by filling, forming a strong elastic reaction force to press and lock the elements, through a spinning action of a connecting ring.

The present application relates to a vacuum flask assembly (1). The vacuum flask assembly (1) comprises a vacuum flask (2) with a push-button lid (5). The push-button lid (5) is movable between an open condition and a closed condition, in which a sealing actuator (15) of the lid (5) is elevated when the lid (5) is in its open condition and retracted when the lid (5) is in its closed condition. The vacuum flask assembly (1) further comprises a container part (21) which is locatable over the lid (5) and is mountable to the vacuum flask (2). When the lid (5) is in its open condition, the container part (21) is configured to act on the sealing actuator (15) as the container part (21) is mounted to the vacuum flask (2), so that the lid (5) is urged to move from its open condition into its closed condition. The present application also relates to a container (3) for a vacuum flask (2) and a baby bottle kit.

The present application relates to a vacuum flask assembly (1). The vacuum flask assembly (1) comprises a vacuum flask (2) with a push-button lid (5). The push-button lid (5) is movable between an open condition and a closed condition, in which a sealing actuator (15) of the lid (5) is elevated when the lid (5) is in its open condition and retracted when the lid (5) is in its closed condition. The vacuum flask assembly (1) further comprises a container part (21) which is locatable over the lid (5) and is mountable to the vacuum flask (2). When the lid (5) is in its open condition, the container part (21) is configured to act on the sealing actuator (15) as the container part (21) is mounted to the vacuum flask (2), so that the lid (5) is urged to move from its open condition into its closed condition. The present application also relates to a container (3) for a vacuum flask (2) and a baby bottle kit.

Provided are thermally insulating components that include sealed joints between the walls that define an insulating space therebetween. Also provided are related methods of forming and using the disclosed components. Additionally provided are thermally insulating components that include a positive thermal coefficient material.