An actively heated or cooled food container can have a lid movable between an open and a closed position and an insulated body to which the lid can be attached. The insulated body can have a sidewall that defines a perimeter of the container body and a base, the sidewall and base defining one or more chambers that can be sealed by the lid. The food container can have a temperature control system that can include one or more heating or cooling elements in thermal communication with one or both of the sidewall and the base and operable to heat or cool one or both of the sidewall and the base to thereby heat or cool the one or more chambers in the food container.

A heat loss protection lid for a thermal liquid container system, wherein the heat loss protection lid comprises a central body, a liquid ingress opening formed within the central body, a liquid dispensing opening formed within one of a peripheral edge of the central body or a lip formed around the peripheral edge of the central body. and a concealed air intake hole.

A temperature controlled storage assembly for food and beverages includes a housing, which defines an interior space, and a bowl. The housing has a recess extending into an upper face thereof. A thermal energy storage material can be selectively positioned in the interior space. The bowl comprises a bottom, which has a lower sidewall coupled thereto and extending therefrom. The lower sidewall has an upper sidewall coupled thereto and extending therefrom to define a top of the bowl. The top is open for insertion of an article into the bowl, such as a foodstuff or a beverage. The lower sidewall is inserted into the recess to selectively engage the housing. At least one of the bottom and the lower sidewall of the bowl transfer heat between the thermal energy storage material and the article.

A heat exchanging thermal liquid container system that comprises a main body at least partially defining a liquid reservoir structured and operable to retain a liquid, and a phase change material (PCM) liner comprising a PCM liner PCM having a selected melting temperature, and/or at least one PCM pod. Each of the at least one PCM pod(s) comprising a respective PCM pod PCM having a respective selected melting temperature. Wherein the PCM liner and/or the at least one PCM pod are disposable within the liquid reservoir such that when a liquid is disposed within the liquid reservoir the liquid will contact at least one of the PCM liner and the at least one PCM pod such that thermal energy can be exchanged between the liquid and the respective at least one of the PCM liner PCM and the at least one PCM pod PCM.

A water bottle capable of freely adjusting temperature and a method for vacuumizing a sealed space thereof. The vacuumizing method includes: injecting a low-boiling point liquid into a sealed space between an inner container and an outer shell through a liquid injection hole; after the liquid injection is completed, placing a bottle mouth portion of a water bottle upside down, so that the low-boiling point liquid flows to the bottle mouth portion; heating the water bottle to vaporize the low-boiling point liquid, where since the specific gravity of the gas generated after vaporization is greater than the specific gravity of air, the air in the sealed space is lifted upward and discharged from the sealed space through the liquid injection hole; and after heating for a period of time, closing the liquid injection hole to form a vacuum or semi-vacuum state in the sealed space. The traditional vacuumizing method cannot perform vacuumizing after the conventional hand warming bottle or icing bottle is filled with a heat-conducting liquid. According to the present invention, the principle that the vaporization temperature of the low-boiling point liquid is low and the gas generated after vaporization is heavier than air is cleverly utilized for performing vacuumizing, thereby resolving the problem that the traditional vacuumizing process cannot perform vacuumizing after the sealed space is filled with the liquid.

A heat exchanging liquid container system comprising a main body; a phase change material (PCM) module disposable within the main body; a PCM disposed within the PCM module; a liquid reservoir defined by the main body and/or the PCM module configured to have liquid disposed therein having a first temperature; and a temperature conditioning channel formed along a wall of the PCM module and/or through the PCM module such that the temperature conditioning channel is in thermal contact with the PCM. The temperature conditioning channel configured to provide a flow path through which the liquid can flow to dispense the liquid from the liquid reservoir such that the liquid will be in thermal contact with the PCM while being dispensed. The PCM configured to exchange thermal energy with the liquid and thereby condition the liquid to be dispensed at a second temperature that is within a desired temperature range.

A self-heating container includes a first substance and a second substance that are adapted to produce an exothermic reaction upon contact with each other, a soluble material between the first substance and the second substance, a frangible membrane physically separating the second substance from the soluble material, and a means for rupturing the frangible membrane.

A temperature control cup includes a cup body and a cup cover, and the cup cover is covered on the cup body. The cup body is provided with a cup outer shell, a cup middle shell, and a cup inner wall in order from the outside to the inside. A vacuum heat insulation layer is provided between the cup shell and the cup middle shell. A gas getter is provided in the vacuum heat insulation layer at the bottom of the cup body. A phase change material layer is provided between the middle shell and the inner wall of the cup body. The bottom center of the cup shell is recessed inward with a small through-hole, and the through-hole is sealed with glass after melting at high temperatures.

A thermal liquid container system comprising a main body, a phase change material (PCM) liner disposed within the main body having a PCM disposed therein, a liquid reservoir defined by PCM liner, a liquid dispensing partition disposed within the liquid reservoir such that the liquid reservoir is partitioned into a temperature conditioning channel and a liquid retention chamber, and a lid comprising a liquid ingress and a liquid dispensing opening, the temperature conditioning channel for placing a liquid passing therethrough in thermal contact with the PCM whereby thermal energy is exchanged between the liquid flowing through the temperature conditioning channel and the PCM such that the liquid is dispensed at a temperature that is within a desired temperature range determined by the selected PCM melting temperature.

A heat exchanging liquid container system comprising a main body; a phase change material (PCM) module disposable within the main body; a PCM disposed within the PCM module; a liquid reservoir defined by the main body and/or the PCM module configured to have liquid disposed therein having a first temperature; and a temperature conditioning channel formed along a wall of the PCM module and/or through the PCM module such that the temperature conditioning channel is in thermal contact with the PCM. The temperature conditioning channel configured to provide a flow path through which the liquid can flow to dispense the liquid from the liquid reservoir such that the liquid will be in thermal contact with the PCM while being dispensed. The PCM configured to exchange thermal energy with the liquid and thereby condition the liquid to be dispensed at a second temperature that is within a desired temperature range.