A beverage container assembly is provided comprising a beverage container body, a stopper member removably attachable to the beverage container to seal a beverage container aperture thereof, and a thermal insulation member removably attachable to an upper body portion of the beverage container body. The thermal insulation member has a sidewall extending downwardly from an upper portion and defining a downwardly opening cavity within which the upper body portion and the stopper are positioned. The sidewall and the upper portion of the thermal insulation member each include an inner wall and an outer wall spaced apart from the inner wall. An insulation chamber is disposed between the inner and outer walls. The thermal insulation member includes an engagement portion adapted to engage with a corresponding engagement portion of the upper body portion to removably attach the thermal insulation member thereto.

A vacuum insulated container includes a body defined with inner and outer walls, a lid portion having a cap that is arranged to be actuated between open and closed states, and a removable cup that has a threaded connection to the body. Upon the cup being engaged with the body, an interior surface of the cup may contact the cap, or be arranged in proximity to the cap, in order to maintain the cap in the closed state. When the cup is removed from the body, the cap may be actuated between the open and closed states. In the open state, fluid may be accessed through an opening in the lid portion, where the opening conforms to a user's mouth to facilitate drinking. The fluid also may be poured from the container into the cup, which may include a liner or foam insulation.

A food storage container is disclosed. The food storage container has a one or more water tight compartments. The food storage container can have an insulated component that can maintain food at substantially constant temperature over a relatively long period of time. The insulated component can be secured to the food storage container with a securing insert that prevents the insulated component from moving or rotating when in use. The insulated component can be removed. The insulated component can have a lid with an opening lever feature that makes it easy for users to open the lid. The food storage container can have a removable divider that can be used to create a plurality of smaller compartments. The food storage container can have a latch and hinge assembly to close the lid and tray. The food storage container can have an integral handle to provide a carrying solution.

A method of making a container includes applying an insulating material in an inactive form to form a layer on a first substrate. The applied insulating material includes expandable microspheres. The method further includes joining a second substrate to the first substrate to adhere the first substrate to the second substrate and to create at least a portion of a multi-layer composite having at least one air gap between the first substrate and the second substrate. The method further includes heating the applied insulating material to activate expandable microspheres thereof to form expanded microspheres. The method further includes increasing the thickness of the applied insulating material layer to thereby increase the volume of the air gap between the first substrate and the second substrate of the multi-layer composite by the heating of the applied insulating material. The method further includes forming the multi-layer composite into a container having expanded microspheres.

A thermal stabilization vessel may include a double walled tube. The tube may have an outer wall, an inner wall, and a sealed off volume located between the inner and outer walls. A removable base may close off a bottom opening of the tube and conduct heat to or from a container placed within the vessel. A top may partially close off a top opening of the tube. The top may include an annulus of elastomeric material. The annulus may have a plurality of resilient tabs extending radially inward toward a central axis of the tube. When a container such as a bottle of wine is placed within a vessel, the tabs of the annulus may resiliently deflect as needed to accommodate the container and then restrict air exchange between an ambient environment and a space located interior to the inner wall of the tube and exterior to the container.

An insulating container can be configured to retain a volume of liquid, and include a canister having 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 opening can be sealed by a spout adapter, the spout adapter having a spout channel extending between the internal reservoir and a spout opening, smaller than the opening of the canister. The spout opening may be sealed with a cap having a magnetic top surface, and the spout adapter may be further removably coupled to a lid that may be used as a cup into which a volume of the liquid can be poured. In addition, spout adapter assembly with an adapter that releasably attaches to the canister and a plug that is received within the adapter that moves to place the spout adapter assembly into an open and a closed orientation. The plug may have a means to provide tactile feedback to a user that the spout adapter assembly is in an optimal pouring condition.

A method of making a container includes applying an insulating material in an inactive form to form a layer on a first substrate. The applied insulating material includes expandable microspheres. The method further includes joining a second substrate to the first substrate to adhere the first substrate to the second substrate and to create at least a portion of a multi-layer composite having at least one air gap between the first substrate and the second substrate. The method further includes heating the applied insulating material to activate expandable microspheres thereof to form expanded microspheres. The method further includes increasing the thickness of the applied insulating material layer to thereby increase the volume of the air gap between the first substrate and the second substrate of the multi-layer composite by the heating of the applied insulating material. The method further includes forming the multi-layer composite into a container having expanded microspheres.

A thermally insulated container comprising: a frusto-conical support base internally comprising a heat source with connection to an external electrical source, a flat support base, an elongated main body of circular section with thermally insulated walls with connectors arranged at the base of said body to electrically link a shielded electrical resistance; a plug with a shutter that acts as a closure of the main body mounted in the mouth of said body by means of a thread and comprising a safety pressure element. The thermally insulated container is particularly adequate for heating water to two temperature settings to be used to prepare mate beverage or to prepare other infusions. In a first embodiment the container holds 500cc of water and in another embodiment it holds one liter of water.

A double-walled insulated container including an outer member being formed of a metal material and comprising a substantially tubular sidewall having a first end to engage a first lid assembly and a second end comprising a recess to receive therein a second lid assembly, an inner member being formed of a metal material and including a substantially annular sidewall defining a receptacle having a first end and a second end, and a ledge formed in the sidewall between the first end and the second end and extending completely around and from the sidewall into the receptacle to define an upper portion of the receptacle to receive a beverage container supported by the ledge and a lower portion of the receptacle to receive a thermal transfer material, and an insulating member being formed of a metal material and disposed in an annular space defined between the sidewalls of the outer and inner members.

The present invention relates to a self-heating pouch for heating consumables and method of manufacture thereof. The self-heating pouch includes a flexible housing and a sealable cap. The flexible housing includes an internal pouch, an external pouch, and at least one frangible button. The internal pouch includes an inner surface and an outer surface. The inner surface of the internal pouch is configured to enclose the consumables. The external pouch is attached internally to the outer surface of the internal pouch. The at least one frangible button is included between the external pouch and the internal pouch. The at least one frangible button is configured to release a liquid to react with a heating agent and initiate heating of the consumables. The sealable cap is attached to top of the flexible housing and configured to dispense the consumables.