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.

A storage container apparatus is provided for storing air sensitive materials under a vacuum. The apparatus includes having a cylindrical container body opened at its upper end and a cap apparatus with an integral air pump to evacuate air from the container body to create a vacuum. The cap apparatus comprises an inner cap with a one-way air valve and an outer cap. The outer cap is slidably nested over the inner cap and confines a central air chamber which fills with air from the container body through the one-way air valve when pulled upwardly in a reciprocating motion. In the down stroke the air is evacuated from the air chamber through vents. The outer cap may include locking mechanism and vacuum level indicator. The outer cap may include an activated carbon cloth insert that suppresses odors from the material stored in the container.

A storage container apparatus is provided for storing air sensitive materials under a vacuum. The apparatus includes having a cylindrical container body opened at its upper end and a cap apparatus with an integral air pump to evacuate air from the container body to create a vacuum. The cap apparatus comprises an inner cap with a one-way air valve and an outer cap. The outer cap is slidably nested over the inner cap and confines a central air chamber which fills with air from the container body through the one-way air valve when pulled upwardly in a reciprocating motion. In the down stroke the air is evacuated from the air chamber through vents. The outer cap may include locking mechanism and vacuum level indicator. The outer cap may include an activated carbon cloth insert that suppresses odors from the material stored in the container.

A container has a chamber and a phase change material (PCM) that can remove heat from the chamber. The container can have a thermal conductor movably coupled in the container between a retracted position and a deployed position, where in the deployed position, while on a heat sink unit, the thermal conductor can draw heat from the PCM to solidify or charge the PCM, which can then maintain the chamber in a chilled state for a prolonged period of time. The container can have one or more heating elements in thermal communication with the chamber and operable to add heat to the chamber to increase or maintain a temperature of the chamber in a heated state for a prolonged period of time.

A container has a chamber and a phase change material (PCM) that can remove heat from the chamber. The container can have a thermal conductor movably coupled in the container between a retracted position and a deployed position, where in the deployed position, while on a heat sink unit, the thermal conductor can draw heat from the PCM to solidify or charge the PCM, which can then maintain the chamber in a chilled state for a prolonged period of time. The container can have one or more heating elements in thermal communication with the chamber and operable to add heat to the chamber to increase or maintain a temperature of the chamber in a heated state for a prolonged period of time.

An article includes walls defining an insulating space therebetween and a vent forming an exit for gas molecules during evacuation of the space. A distance separating the walls is variable in a portion adjacent the vent such that gas molecules are directed towards the vent imparting a greater probability of molecule egress than ingress such that deeper vacuum is developed without requiring getter material. The variable-distance portion may be formed by converging walls. Alternatively, a portion of one of the walls may be formed such that a normal line at any location within that portion is directed substantially towards a vent opening in the other wall.

Provided are thermally insulated modules that comprise a first shell and a first component having a first sealed evacuated insulating space therebetween and a current carrier configured to give rise to inductive heating. Also provided are methods of utilizing the disclosed thermally insulated modules in a variety of applications, including additive manufacturing and other applications.

An insulated container is described. The insulated container includes a double-walled structure having a closed end, an open end, and a side wall extending between the closed and open ends. The side wall and the closed end of the insulated container together form a hollow interior. A glass structure may be arranged within the hollow interior. The glass structure includes a body having an open upper end and a base end, and a sipping portion extending from the upper end. The sipping portion may include a sipping end and a shoulder end spaced apart from the sipping end. The sipping portion protrudes from the open end of the double-walled structure. A collar is positioned over the sipping portion of the glass structure thereby forming a sipping surface.

A beverage container system may include a vessel having an interior volume for containing a beverage and shell having an interior volume for removably coupling vessel therein. The shell may include an inner wall, an outer sidewall, and a sealed volume between the inner wall and the outer wall. The sealed volume may be at a vacuum pressure. The vessel may be constructed from glass while the shell may be constructed from a durable material such as stainless steel.

A beverage container system may include a vessel having an interior volume for containing a beverage and shell having an interior volume for removably coupling vessel therein. The shell may include an inner wall, an outer sidewall, and a sealed volume between the inner wall and the outer wall. The sealed volume may be at a vacuum pressure. The vessel may be constructed from glass while the shell may be constructed from a durable material such as stainless steel.