An composite heater is disclosed. The heater may include a base additively manufactured from a first matrix material, and a heating element additively manufactured adjacent the base from a second matrix material and an electrically and thermally conductive fiber that is at least partially encased in the second matrix material. The heater may also include a control mechanism configured to selectively complete a circuit between a power supply and the electrically and thermally conductive fiber.

In order to provide a manufacturing method of the three-dimensional shaped object having a more proper heat property to be used as a metal mold, there is provided a method for manufacturing a three-dimensional shaped object by alternate repetition of a powder-layer forming and a solidified-layer forming, the repetition comprising: (i) forming a solidified layer by irradiating a predetermined portion of a powder layer with a light beam, thereby allowing a sintering of the powder in the predetermined portion or a melting and subsequent solidification of the powder; and (ii) forming another solidified layer by forming a new powder layer on the formed solidified layer, followed by irradiation of a predetermined portion of the newly formed powder layer with the light beam, wherein the three-dimensional shaped object is manufactured such that it has a heat source element in the three-dimensional shaped object, and also has a surface in a form of a concavity-convexity, and wherein a main surface of the heat source element and the surface of the concavity-convexity have the same shape as each other.

A method of manufacturing a heater for an aerosol-generating device is provided, the method including: forming a heater body including a heater body frame and a heating element, the heater body defining at least a portion of a boundary of a heating chamber configured to receive an aerosol-generating article such that the heating element is configured to heat the heating chamber, at least part of the heater body frame being manufactured by additive manufacturing. A method of manufacturing an aerosol-generating device; and a heater; and an aerosol-generating device are also provided.

A thermal roller (1) includes: a cylindrical body (2) extending along a longitudinal direction (X-X), the cylindrical body (2) including at least one inner tubular element (3) and at least one outer tubular element (4) that is concentrically arranged around the inner tubular element (3), the inner tubular element (3) includes an outer diameter d and the outer tubular element 4 includes an inner diameter D, being D>d; two hubs (6), each arranged at one end of the cylindrical body (2); at least one heat-exchange chamber (10) realized between the inner tubular element (3) and the outer tubular element (4). The roller includes: a coating layer (11) for the inner tubular element (3) made of plastics, and at least one helical channel (13) between the coating layer (11) and the outer tubular element (4). The helical channel (13) is realized at least partially in the coating layer (11).

An endless-belt shaped heating element is produced by: dispersing annealed stainless-steel fibers in the heat-resistant resin or a precursor thereof; and, producing a molded article of the heat-resistant resin in which the annealed stainless-steel fibers are dispersed.

A method for transferring objects onto a substrate, or running substrate, the objects to be transferred being placed in a transfer area containing a carrier liquid forming a conveyor, the objects being held by a compact film of particles floating on the carrier liquid of the transfer area, within which the objects are displaced with the film of particles to be transferred onto the substrate, making at least one connector on at least one of the objects, the connector being made by a substance comprising a polymerizable compound, put in contact with the object arranged within the transfer area, and then by polymerization of the substance.

A thermal conductive strip with a power supply terminal includes: a carbon fiber unit including a carbon fiber connecting end; a plastic envelope which encapsulates the carbon fiber unit and has a length smaller than a length of the carbon fiber connecting end, and further includes a broken portion which covers a part of the carbon fiber connecting end; and the power supply terminal sleeved onto the broken portion and the carbon fiber connecting end, and including a clamping section for clamping the broken portion, and an electrically conductive section for contacting the carbon fiber connecting end. The power supply terminal is partially clamped on the plastic envelope and partially eclectically connected to the carbon fiber, which improves the yield rate and the bending durability of the thermal conductive strip of the present invention.

The invention pertains to a heating or cooling element comprising a carrier mat. a first tube which is attached in meander or spiral form to the carrier mat, wherein the heating or cooling element can be rolled up; and wherein the carrier mat is made of polymer material, and the carrier mat is cut and bent around the first tube to connect the first tube to the carrier mat.

The present invention relates to a heating element composition capable of three-dimensional molding and a film heater formed therefrom. Specifically, the present invention relates to a heating element composition capable of three-dimensional molding and a film heater formed therefrom, wherein the heating element composition has high extensibility and excellent high temperature durability which is in a conflicting relationship with extensibility, so that mechanical damage such as cracks during stretching can be suppressed, has the characteristic of being stably maintained in a molded shape rather than being restored to an original shape after molding, like conventional stretchable materials, can minimize the change rate of resistance when deformed by three-dimensional molding, can be cured at 150 C. or less, and can form a heating element by various printings or coatings so as to be applied to various film heaters.

A cooking apparatus includes a non-ferrous cooking vessel configured to receive food. The cooking apparatus also includes a ferrous cooking vessel cover that is configured for placement over a top of the non-ferrous cooking vessel. The cooking apparatus also includes one or more induction heating elements suspended from the ferrous cooking vessel cover, and a radiation source. The radiation source is configured to deliver electromagnetic radiation to the ferrous cooking vessel cover and the one or more induction heating elements such that the ferrous cooking vessel cover and the one or more induction heating elements are heated.