The present invention relates to a portable thermal container (1) for consumer products (2′) comprising at least a storing chamber (2) of the consumer products (2′) and at least a reaction chamber (4) of a reagent component (5′) and a of a reactive component (5″), wherein the reaction chamber (4) extends substantially entirely along the dimension of the largest dimension of the portable thermal container (1) and the storing chamber (2) is arranged side-by-side to the reaction chamber (4) to maximize the thermal exchange between the reaction chamber (4) and the storing chamber (2) in an homogeneous way, and the reaction chamber (4) comprises at least a storing portion and at least an expansion portion, wherein the total volume of said expansion portions is greater than the total volume of said storing portions to allow the safe expansion of the chemical reaction gases in said reaction chamber (4).

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.

A temperature-regulating apparatus is provided to rapidly cool a beverage to a desired temperature. In some variations, the geometry of the temperature-regulating apparatus is configured to rapidly cool a beverage incorporating one or more inner portions that contain a temperature regulating material, such as a phase change material having a high heat capacity. The geometry of the interior of the container may be configured to aid in rapid heat transfer between the beverage therein and the outer shell of the inner portion and may have a length to width aspect ratio of at least 4:1. The inner portion may be formed between the exterior wall of the container and by a single piece of formed metal that extends along the length, width and base walls to form the interior for receiving a beverage. The cavity formed between the outer shell and the exterior wall may be at least 15 mm deep.

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.

A thermal insulation cup with a tilted neck includes an outer case and an inner tank arranged inside the outer case. The outer case includes a first cup wall, a second cup wall, and a case bottom that together define a cavity with an open end. The end of the first cup wall has a less height than that of the end of the second cup wall. The first cup wall gradually tilts inward in the direction from the bottom to the end. The second cup wall gradually tilts inward in the direction from the bottom to the end. The inner tank includes a drinking port, a first inner wall, a second inner wall, and a bottom that together define a cavity with an open end. The end of the first inner wall has a less height than that of the second inner wall. The first inner wall gradually tilts inward in the direction from the bottom to the end, and the second inner wall gradually tilts inward in the direction from the bottom to the end. The ends of the outer case and the inner tank respectively define an opening and a drinking port that are inclined to the same side. The opening is welded and fixed to the lower part of the drinking port.

The disclosure discloses a multi-functional beverage container that includes a multi-walled evacuated vessel body; an integrated juicing element to releasably nest within the multi-walled evacuated vessel body; a multi-walled vessel top that realeasably seals to the multi-walled vessel body and to receive the juicing element; and a multi-walled cap that realeasably seals to the multi-walled vessel top. The container may further comprise a planar straining element for straining purposes, various sealing gaskets, integrated volumetric measuring indicators, a fluid within the dual walls comprising a freezing point below at least zero degrees Celsius to maintain a chilled nature of a stored liquid within the container. The container may comprise thermo-chromatic paint to indicate a representative temperature has been achieved, external portions to comprise textured elements to facilitate grasping and twisting, and an internal sensor to wirelessly communicate a measured weight to a secondary wireless device.

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 shock-proof mineral container and mounting structure thereof, which provides a heat insulation container with a liner formed using mineral material. The liner is provided with shock-proof protection and a mounted assembly structure. During the process of assembling the single ended suspended configuration, a blocking member having an elastic effect is inter-connected between an annular neck configured on the mineral liner and an upper link opening joined to an outer cylinder, and the elastic strain of the blocking member is used to absorb shock waves occasionally produced by an external force when carrying the container, thereby safeguarding the structural safety of the hard and brittle mineral liner. In addition, the structure is supplemented with a cylinder liner, which adds to the heat insulation capacity of the container and maintains the stability of the mineral liner.

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.