An induction heatable cartridge for use with an induction heating assembly includes a solid vaporisable substance and at least one ring-shaped induction heatable susceptor held within and surrounded by the vaporisable substance. The susceptors are held in position such that, when the cartridge is positioned in an induction circuit in use, different regions of the outer edge of the one or more susceptors are at different distances from the induction circuit to provide different heating characteristics in the different regions. The centres of each of the at least one susceptors are aligned along a common axis.

An aerosol-generating device includes a housing having an opening configured to receive an aerosol-generating article; an accommodating space configured to accommodate the aerosol-generating article inserted through the opening; a heat-dissipating structure comprising an inner wall forming the accommodating space, and an outer wall surrounding the inner wall such that an inner space is formed between the inner wall and the outer wall; and a coil arranged between the outer wall and the housing, and configured to generate an induced magnetic field, wherein the inner wall is configured to generate heat by the induced magnetic field generated from the coil.

An inductive heater assembly for an aerosol-generating device is provided, the assembly including: at least one inductor coil configured to generate a varying magnetic field when a varying electric current flows through the coil; at least one susceptor arranged to be penetrated by the magnetic field generated by the coil to heat the susceptor; at least one temperature sensor arranged to determine a temperature of the susceptor, the temperature sensor includes first and second resistive sensing elements, the first element being connected to the second element, and the first element being positioned relative to the second element such that a current induced in the first element by the magnetic field opposes a current induced in the second element by the magnetic field. An aerosol-generating device including the inductive heater assembly, control circuitry, and a power source, is also provided.

An inductive heating element for an aerosol-generating system is provided, the inductive heating element including: a cavity configured to receive an aerosol-forming substrate to be heated by the inductive heating element; a first susceptor; a second susceptor; and an intermediate element disposed between the first susceptor and the second susceptor, the intermediate element being gas permeable, the intermediate element including at least one of: a thermally insulative material configured to thermally insulate the first susceptor from the second susceptor, and an electrically insulative material configured to electrically insulate the first susceptor from the second susceptor. An inductive heating arrangement and an aerosol-generating device are also provided.

An inductive heating element for an aerosol-generating system is provided, the inductive heating element including: a first susceptor, the first susceptor being a tubular susceptor defining an inner cavity configured to receive an aerosol-forming substrate; a second susceptor, the second susceptor being a tubular susceptor defining an inner cavity configured to receive aerosol-forming substrate; and a separation between the first susceptor and the second susceptor, the separation thermally insulating the first susceptor from the second susceptor. An inductive heating arrangement, an aerosol-generating device, and an aerosol-generating system are also provided.

There is provided a method of controlling an aerosol-generating system including an aerosol-generating device including a cavity to receive an aerosol-forming substrate, an inductive heating arrangement including an inductive heating element including a susceptor heatable by penetration with a varying magnetic field to heat the substrate, first and second inductor coils, and a power supply; the method including initiating heating of the substrate in the cavity by a first varying current in the first coil to generate a first varying magnetic field that heats a first portion of the element, and controlling the first current to increase a temperature of the first portion with a first profile; and subsequently driving a second varying current in the second coil to generate a second varying magnetic field that heats a second portion of the element, and controlling the second current to increase a temperature of the second portion with a second profile.

A food delivery system comprising an induction heating apparatus, an induction-heatable apparatus, and a food delivery cart. The induction heating apparatus includes an induction heating element and an electronic system including a communication element configured to communicatively link to an ordering system. The induction-heatable apparatus is configured to be heated via the induction heating apparatus and includes an RFID tag configured to store information of food being heated and information of an intended recipient or intended destination of the food. The food delivery cart includes an induction heating element configured to warm the induction-heatable apparatus and hence the food and an electronic system including an RFID reader to determine information corresponding to the food, augment the information, and transmit the augmented information a central monitoring system.

An induction heated tool system for receiving and heating polymer-fiber components from a starting temperature to a target temperature includes a tool part having a receiving cutout, the tool part formed from a thermally dimensionally stable material so it has a coefficient of thermal longitudinal expansion less than 10×10.sup.−6 K.sup.−1, or less than 5×10.sup.−6 K.sup.−1, or less than 4×10.sup.−6 K.sup.−1 in the plane of the largest dimension of the receiving cutout, at temperatures between the starting and target temperatures. A receiving cutout for receiving a polymer-fiber component is in the tool part, the receiving cutout delimited by a receiving surface portion so a polymer-fiber component received in the receiving cutout can lie against the receiving surface portion. A susceptor element includes a ferromagnetic material with a first Curie temperature. The susceptor element is on a surface portion of the tool part outside the receiving cutout and the receiving surface portion.

A heating body of an epitaxial growth device is provided. The heating body (1) includes a supporting base (11) and a tray (2). The supporting base (11) extends along an axis of the epitaxial growth device (100). The tray (2) is mounted on the supporting base (11) to support a substrate. The supporting base (11) is configured to generate heat by an electromagnetic induction with an induction coil, which in turn heats the tray (2). The tray (2) is configured to transfer heat to the substrate to heat the substrate. The supporting base (11) is provided with a temperature control channel (3), which is close to an edge of the tray (2), and along a direction perpendicular to a surface of the supporting base (11), a part of a projection of the temperature control channel (3) is on the tray (2).

The present invention relates to a multi-layer susceptor assembly for inductively heating an aerosol-forming substrate which comprises at least a first layer and a second layer intimately coupled to the first layer. The first layer comprises a first susceptor material. The second layer comprises a second susceptor material having a Curie temperature lower than 500° C. The susceptor assembly further comprises a third layer intimately coupled to the second layer. The third layer comprises a specific stress-compensating material and specific layer thickness for compensating differences in thermal expansion occurring in the multi-layer susceptor assembly after a processing of the assembly such that at least in a compensation temperature range an overall thermal deformation of the susceptor assembly is essentially limited to in-plane deformations. The compensation temperature range extends at least from 20 K below the Curie temperature of the second susceptor material up to the Curie temperature of the second susceptor material.