Disclosed herein is a high-power device for supplying a radiofrequency electromagnetic field to a waveguide. The device comprises a magnetron configured to supply a radiofrequency electromagnetic field to a waveguide and a control unit configured to control the magnetron to output radiofrequency energy to the waveguide. The magnetron comprises a high voltage pulse connection enclosed in an enclosure, a heater connection configured to allow an electrical connection to penetrate the enclosure and a mechanism configured to transmit data between the magnetron and the control unit.

Disclosed herein is a high-power device for supplying a radiofrequency electromagnetic field to a waveguide. The device comprises a magnetron configured to supply a radiofrequency electromagnetic field to a waveguide and a control unit configured to control the magnetron to output radiofrequency energy to the waveguide. The magnetron comprises a high voltage pulse connection enclosed in an enclosure, a heater connection configured to allow an electrical connection to penetrate the enclosure and a mechanism configured to transmit data between the magnetron and the control unit.

An electronic system includes an external jacket; a wall of an internal cavity that is to be cooled; at least one fixed connection fixing the external wall of the internal cavity that is to be cooled to the external jacket; a heat-transport fluid cooling circuit comprising grooves on the external surface of the wall of the internal cavity and a sleeve comprising a flexible portion positioned flush with the external surface of the external wall of the internal cavity, thereby forming mini-canals with said grooves; a radial extension of the wall of the internal cavity creating connecting points intended to hold the sleeve in place; and a space between the external jacket and the sleeve at the flexible portion of the sleeve.

The invention relates to anti-multipactor coating deposited onto a substrate that can be exposed to the air and its procedure of obtainment by simple chemical methods. Furthermore, the present invention relates to its use for the fabrication of high power devices working at high frequencies.

The invention relates to anti-multipactor coating deposited onto a substrate that can be exposed to the air and its procedure of obtainment by simple chemical methods. Furthermore, the present invention relates to its use for the fabrication of high power devices working at high frequencies.

In the present invention, a pressure measurement device for determining the vacuum level within the evacuated housing of a vacuum electrode device is provided that includes an electrically conductive enclosure secured to an interior surface of the housing, an electrically conductive electrode extending through an aperture in the housing, the electrode having a tip at one end positioned within the interior of the housing inside the enclosure to define a gap between the tip and the enclosure and a conductive lead at a second end disposed outside of the housing, and a voltage source connected to the conductive lead to supply a voltage potential to the tip of the electrode. A voltage difference produced between the electrode and the enclosure ionizes gas within the enclosure causing a measurable current to flow between the electrode and the enclosure which can be used to determine the vacuum level in the housing.

An apparatus for generating electromagnetic waves is envisaged relating to the field of electromagnetic wave generating systems. The apparatus provides efficient radio frequency amplification, facilitates low loss electromagnetic generation, enables efficient utilization of kinetic energy of electrons, and works for different radio frequencies. The apparatus comprises an evacuated envelope, a pair of metal plates, a resonator, an electron gun, a magnetic field generator, and a pick-up loop. The evacuated envelope defines a space therewithin. The pair of metal plates defines a passage therebetween. The resonator is coupled to the pair of metal plates. The electron gun emits controlled bursts of electrons into the passage. The magnetic field generator is configured to generate electromagnetic waves. The pick-up loop extracts the generated electromagnetic waves.

An apparatus for generating electromagnetic waves is envisaged relating to the field of electromagnetic wave generating systems. The apparatus provides efficient radio frequency amplification, facilitates low loss electromagnetic generation, enables efficient utilization of kinetic energy of electrons, and works for different radio frequencies. The apparatus comprises an evacuated envelope, a pair of metal plates, a resonator, an electron gun, a magnetic field generator, and a pick-up loop. The evacuated envelope defines a space therewithin. The pair of metal plates defines a passage therebetween. The resonator is coupled to the pair of metal plates. The electron gun emits controlled bursts of electrons into the passage. The magnetic field generator is configured to generate electromagnetic waves. The pick-up loop extracts the generated electromagnetic waves.

A magnetron is provided and includes a tube body with a plurality of communicated first cavities therein, a plurality of anodes in the first cavities including a cylinder and a plurality of vanes, outer ends of the vanes are connected with an inner circumferential surface of the cylinder; a first resonant cavity and a second resonant cavity are formed between the adjacent vanes, the cylinder is provided with a plurality of coupling slots arranged at intervals and running through the cylinder to communicate the first resonant cavity with the first cavity; a plurality of cathode arranged in and coaxially with the cylinder; the cathodes and inner ends of the vanes are spaced apart; at least part of the cathodes are located inside vanes, and an output slot is defined on the tube body for communicating the first cavity with an outside.

An electrical arrangement, which may, for example be a magnetron, has a sealed chamber and electrically insulating fluid contained within the chamber. A temperature expansion compensation bladder comprising a helical tube is located within the chamber, the helical tube having an end open to ambient atmosphere outside the chamber, and having a closed end within the chamber.