Canteens with storage compartments are described. Such canteens may have a main body with two separate and distinct cavities, each of which may function as a storage compartment. Such two different cavities may be a top cavity and a bottom cavity. Such two different cavities may be longitudinally disposed of each other, such that a bottom portion of the top cavity is disposed above a roof portion of the bottom cavity. A volume of the bottom cavity may extend, at least partially, into a volume of the top cavity in a manner that is radially symmetrical about a shared central longitudinal axis of both the top cavity and the bottom cavity; and in a manner where these two different volumes remained sealed from each other. The top cavity may be for beverages. The bottom cavity may removably store credit cards and/or a smartphone.

An assembly for a portable blender. The assembly having a housing that is configured for coupling to a container. The assembly has at least one battery, a motor electrically connected to the battery, a blade coupled to the motor, and a user input device operable to cause power to be sent from the battery to the motor so that the motor rotates the blade. At least a portion of the blade is positioned outside of the housing so that the blade is configured to be positioned in an interior space of the container when the housing is coupled to the container. The assembly may include a plurality of batteries each positioned radially outward from the motor with the batteries positioned circumferentially around the motor. A portable blender including the assembly and a container. The container having a dual-wall, vacuum insulated construction.

A thermal insulating container for containing substances and maintaining substances at a determined temperature is disclosed. The container has a continuous containment wall which extends in a single body and defines an inner containment region with an opening. The containment wall has a first, or outer layer, of ceramic material, and a second, or inner layer, facing towards the inner containment region of ceramic material and separated from the first layer forming a gap region inside which a vacuum is created. The outer layer has a hole for exit of the air during the step of firing the ceramic material and for extraction of air and creation of the vacuum inside the gap following the firing. The container also has closing means for hermetically closing the hole once the vacuum has been created.

Container assemblies including an insulated cap for sealing the mouth of the container, the insulated cap including an outer shell, an insulation block defining a plurality of elongate voids disposed at least partially within the outer shell, a securing element configured to secure the cap to the container, and a sealing member configured to form a seal between the insulated cap and the container when the insulated cap is secured to the container by the securing element.

A closable container and method of its manufacture, the container having an inner layer, an outer layer, a top and a base, the top inner layer having a coupling mechanism configured to receive a lid that seals the container using a screw top coupling mechanism, the inner layer and the outer layer made of stainless steel, the top inner layer evenly coated with a ceramic layer.

In a vacuum heat insulating double walled container 1, adsorbent blocks 30 are formed in block, and each of the adsorbent blocks 30 disposed on the peripheral surface of a sample storage container 25 is placed on a partition plate 27. Moreover, an inner container 10 is hang in an outer container 3 using a connecting tube 20 formed of a thin material having an uneven outer peripheral surface, and a heat insulating tube 40 is disposed on the inner surface of the connecting tube 20. Further, as to a workpiece carrier 50 as a fixing device, a carrier guide 52 is in close contact with the heat insulating tube 40, and a plate-like portion 54 and a workpiece storage portion 51 are disposed in a non-contact state with respect to the sample storage container 25. As a result, it is possible to suppress the amount of heat transferred from the inner container 10 to the outer container 3, and vibration and impact is less likely to applied to a sample in the workpiece storage portion 51 even if an external force such as impact is applied to the vacuum heat insulating double walled container 1.

An improved thermos is provided. This improved thermos includes an outer thermos and a nestable inner thermos which is structured so as to be nestable within the outer thermos. The thermos includes a lid that is structured to seal the nestable inner thermos and a dual functioning base which is configured in size and shape for physically operating as both (1) a base for the thermos when the dual functioning base is positioned on a bottom portion of the thermos with a friction fit, and (2) a lid for the outer thermos when the dual functioning base is positioned on a top portion of the outer thermos with a friction fit.

An improved thermos lid is provided. The improved thermos lid includes a spout, a vent, and a rotatable valve cover that includes a snorkel. The rotatable valve cover is rotatable so as to either reveal or cover the spout. When the spout is revealed, the snorkel is positioned overtop of the vent, which creates a pathway between the vent and an outside atmosphere.

A liquid storage container that includes a lid and a body. The body defines a storage cavity. The body has a double-walled vacuum insulated layer that defining the storage cavity. A membrane is formed around the double-walled vacuum insulated layer and a coating is formed on the outside of the membrane.

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.