A transportable flask. The transportable flask includes a bottle, where the bottle is configured to hold a liquid beverage. The transportable flask also includes a cap, where the cap is configured to attach to the bottle and prevent removal of the liquid beverage when in position. The transportable flask further includes a first cup, where the first cup is releasably attached to the bottle and a second cup, where the second cup is releasably attached to the cap.

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.

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.

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.

A multiple housing vacuum insulated canister to store plurality of liquid. The canister includes a first housing, a second housing, a third housing, a first rotatable lid, and a second rotatable lid. The first housing includes first top end and first bottom end to store first liquid. The second housing stores solid items having second top end and second bottom end. The second top end of second housing is detachably attached with first bottom end. The third housing having a third top end and third bottom end. The third top end of third housing is detachably attached with second bottom end to store second liquid. The first rotatable lid detachably attached with first top end enables access to first liquid. The second rotatable lid detachably attached with third bottom end having adjustable opening level to control flow of second liquid.

A bowl may be configured to include an outer body, an inner body, an internal cavity between the outer body and inner body, and a bottom. The bottom may further include a plurality of bungholes positioned on the bottom, a circular foot comprising a plurality of bungs configured to engage the plurality of bungholes to secure the circular foot to the bottom.

The present application generally relates to devices and methods for transporting items, and it more specifically relates to insulated carriers for use in carrying temperature-controlled items such as beverages and food.

An insulated bottle includes an inner container having an inner wall that defines an inner chamber within which a product is received. The insulated bottle includes an outer container having an outer wall that defines an outer chamber. The inner container is received within the outer chamber of the outer container. A space is defined between the inner wall and the outer wall. The insulated bottle includes a label shrink wrapped to an outer surface of the inner wall of the inner container. The label is positioned within the space defined between the inner wall and the outer wall.

A heat insulating container is described which can keep a heat insulating state (including cold insulating state) of an inside container stored in an outside container for a long period of time, and improve safety and usability. The heat insulating container may include the outside container having a heat insulating structure; the inside container having a cold insulating structure or a heat insulating structure; and a cover member which is attached to the inside container in a state in which the inside container is stored in the cover member; in which the inside container is stored in the outside container in a non-contact state through the cover member.