A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

An electronic stove incorporates a cylindrical outer shell and a concentric copper heater core. A foil heater surrounds the copper heater core and a heater control PCB carried in the outer shell is connected to the foil heater. A battery assembly has a cylindrical second outer shell carrying a battery pack. A power controller carried in the second outer shell is connected to the battery pack. A connector carriage is engaged between the battery assembly and cylindrical outer shell, extending through the shell of the battery assembly and received in the cylindrical outer shell aligned proximate a lower surface of the first outer shell whereby the lower surfaces of the first outer shell and the second outer shell are in planar alignment. A first contact set of a connector is connected to the heater control PCB. A second contact is connected to the power controller.

Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

An actively heated mug has a body with a chamber that can receive and hold a beverage and a heating element to actively heat the chamber, batteries, and circuitry that controls the operation of the heating element. A user interface is electrically connected to the circuitry and has one or more buttons actuatable a) to turn on the heating element, b) to adjust a temperature setting to one of multiple temperature settings to control the operation of the heating element to heat or maintain the liquid at a user selected temperature setting, and c) to turn off the heating element.

Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

An actively heated drinkware container includes a vessel with a chamber that receives and holds a volume of liquid. The drinkware container includes a heating module with a first heating element operable to heat one portion of the chamber and a second heating element operable to heat another portion of the chamber, the second heating element spaced from the first heating element. Operation of the first and second heating elements generates a circulation current in the volume of liquid in the chamber that mixes the liquid and diffuses a temperature of the liquid to thereby reduce temperature stratification of the liquid in the chamber and so that a temperature of the liquid throughout the volume of liquid in the chamber is approximately uniform.

A wireless charging smart heating cup. The upper end of the cup body comes with a rotating cup mouth, which is provided with a floating cup stopper. The lower end of the cup body comes with a silicone cover. A battery and a heating piece are arranged between the cut body and the silicone cover. A rotating heating switch is arranged on the silicone cover, a chassis is arranged below the silicone cover, a wireless filling coil and a circuit board are arranged in the chassis, a display screen is arranged on the outer side of the chassis, the display screen is connecting with the chassis.

An actively heated or cooled beverage container includes a body chosen from a group consisting of a mug, a cup and a travel mug, the body having a chamber configured to receive and hold a food or beverage therein. The container has a temperature control system that includes a phase change material positioned about at least a portion of the chamber that removes heat from the beverage disposed in the chamber that has a temperature above a predetermined drinking temperature to lower the temperature of the beverage toward the predetermined drinking temperature. One or more heating elements positioned in thermal communication with a different portion of the chamber than the phase change material. The temperature control system also has control circuitry configured to control the operation of the heating element. The temperature control system also includes a ring rotatably coupled to a distal end of the body, the ring configured to rotate about a central axis of the container relative to a proximal portion of the body and to communicate with the control circuitry.

An apparatus for heating beverages is disclosed. The apparatus includes a base and a container for holding liquids. The base has a heater plate that is heated by one or more heater elements attached to the heater plate. A power source in the base provides electricity to the heater elements. The base is removably attachable to the container. The container has an inner cup that sits inside a chassis. The inner cup is made of metal and has an open top for receiving liquid, a circumferential wall, and a closed bottom. The chassis has an open top for receiving a liquid, a circumferential wall, and an open bottom. When the container is attached to the base, the closed bottom of the inner cup is configured to contact the heater plate and receive heat from the heater plate.