An electronic cigarette burner element has a heating wire, a porous ceramic matrix, and outer cover, holes in the outer cover, and a ventilation air passage through the porous ceramic matrix. The heating wire is configured to heat and atomize vape oil. The heating wire is formed with a coil and a pair of leads including a first lead and a second lead. A porous ceramic matrix encapsulates the coil of the heating wire. A heating body is formed when the heating wire is encapsulated by the porous ceramic matrix. An outer cover can be made of metal and can fit over the heating body. A hole is formed on the outer covet to receive vape oil. The vape oil wicks through the porous ceramic matrix like a sponge receiving water. A ventilation air passage is formed along a surface of the porous ceramic matrix.

A warming device for the handrim of a wheelchair is disclosed herein to relieve discomfort caused by manually wheeling a wheelchair in cold and/or wet weather conditions. The warming device includes a hand interface, a mount, and a heating element. The warming device is configured to mount the tube of a handrim. The heating element of the warming device is coupled to an electronics system including a printed circuit board and a battery. The electronics system may be internal to the warming device, or may be housed in an external electronics box mounted similarly to the handrim or the rear wheel of the wheelchair.

The present invention relates to the technical field of atomization and discloses an atomizing device which comprises a heating part, a glass heating element and a quartz holder, wherein the heating part is embedded in the glass heating element, the quartz holder is made with a through-holding cavity, the glass heating element is arranged in the holding cavity, the quartz holder is made with auxiliary air inlet holes on the side wall, and the glass heating element is made with a heating element air passage communicating with the auxiliary air inlet holes so as to meet the user's needs for atomized tobacco tar, thus facilitating atomization of tobacco tar.

The present disclosure discloses a transmission electron microscope in-situ chip and a preparation method thereof. The transmission electron microscope in-situ chip includes a transmission electron microscope high-resolution in-situ gas phase heating chip, a transmission electron microscope high-resolution in-situ liquid phase heating chip and a transmission electron microscope in-situ electrothermal coupling chip. The transmission electron microscope high-resolution in-situ gas phase heating chip and the transmission electron microscope high-resolution in-situ liquid phase heating chip are respectively suitable for gas samples and liquid samples, and the transmission electron microscope in-situ electrothermal coupling chip realizes the multi-functional embodiment of electrothermal coupling. The three transmission electron microscope in-situ chips have the advantages of high resolution and low sample drift rate.

A sheet-shaped conductive member includes a pseudo sheet structure including a plurality of conductive linear bodies arranged at a distance from each other, the conductive linear bodies each being in a wavy shape in a plan view of the sheet-shaped conductive member, the wavy shape being a shape where a second wave is made along an imaginary first wave, the second wave being shorter in amplitude and wavelength than the first wave.

A heater assembly includes a heating element formed in a mesh having a tubular shape, and configured to generate heat when electricity is supplied, and a plurality of electrodes respectively connected to opposite end portions the heating element in a lengthwise direction, extending in a circumferential direction of the heating element, and configured to supply the electricity to the heating element.

Three-way heating shell, in particular for a motor vehicle fluid circuit, said shell being generally T-shaped or Y-shaped and comprising an inner passage having the same shape, in which passage a three-way fluid connection is intended to be housed, the shell being formed by two half-shells (10a) having the same shape which are attached to one another and together define the passage, the half-shells comprising semi-cylindrical surfaces (22, 24, 26) forming portions of the passage, the heating shell being characterised in that it comprises resistive heating circuits (28a, 28b) which are formed in situ on the semi-cylindrical surfaces.

A concrete heating system for electrically melting snow and ice. The concrete heating system generally includes a heating device for embedding in conductive concrete, the device having a spacing member and a plurality of electrically isolated conductors extending outward at an angle from the spacing member along its length. The device also includes a first electrode near the first end of the spacing member, and a second electrode extending outward from the spacing member at the second end. The plurality of conductors conduct an electrical current between the first electrode and the second electrode when the concrete heating device is embedded in conductive concrete and the power source applies a voltage between the first electrode and the second electrode.

An aerosol-delivery system having: an aerosol-generation apparatus with a receptacle for receiving a carrier; a heater; and a carrier for an aerosol precursor with a housing for location in said receptacle. Said housing is configured to provide a fluid pathway between a first end that is disposed in fluid engagement with an inlet of said aerosol-generating apparatus and a second end that is disposed in fluid engagement with an outlet of said aerosol-generating apparatus. A fluid-transfer article is located within said housing, the fluid-transfer article having a first region for holding an aerosol precursor and for transferring said aerosol precursor to an activation surface of a second region of said article, said activation surface disposed at an end of said carrier configured for thermal interaction with a heater of said aerosol-generation apparatus.

The present invention relates to a personal electronic delivery system and a method for delivering a delivery fluid to a person. The system according to the invention comprises: a housing having a first end with an inlet (12) and a second end with an outlet (38); a fluid path substantially extending between the inlet and the outlet; a buffer (30) for holding a delivery fluid, and connecting means configured to transfer delivery fluid to the fluid path; and a heater (32) that is provided in, at or close to the fluid path configured for heating the delivery fluid such that at least a part of the delivery fluid atomizes and/or vaporizes in the fluid path, and an energy source (18) configured for providing energy to the heater,