A thermal increase system includes one or more multi-level electrodes configured to radiate electromagnetic energy into a cavity in response to receiving a radio frequency (RF) signal from an RF signal source. Each multi-level electrode is positioned adjacent to a wall of the cavity, and each multi-level electrode includes a base portion coupled to an elevated portion. A radiating surface of the elevated portion is at a height of at least 0.5 centimeters (cm) from a radiating surface of the base portion.

A thermal increase system includes one or more multi-level electrodes configured to radiate electromagnetic energy into a cavity in response to receiving a radio frequency (RF) signal from an RF signal source. Each multi-level electrode is positioned adjacent to a wall of the cavity, and each multi-level electrode includes a base portion coupled to an elevated portion. A radiating surface of the elevated portion is at a height of at least 0.5 centimeters (cm) from a radiating surface of the base portion.

A dielectric heating device includes a first electrode and a second electrode that face an object to be heated and to which an AC voltage is applied, and a coil that is electrically coupled in series to the first electrode. A linear distance between one end and the other end of the coil is equal to or smaller than a linear distance between the one end and a central portion of the coil in a magnetic path direction of the coil.

Provided is a dielectric heating apparatus for heating a first ink and a second ink that adhere to a medium. The first ink contains carbon black, and the second ink does not contain carbon black. The dielectric heating apparatus includes: a first electrode unit as an electrode unit configured to heat the first ink and the second ink, the first electrode unit including a first electrode and a second electrode that face the medium; and a first voltage application unit configured to apply an AC voltage having a frequency of 300 MHz or more and 300 GHz or less to the first electrode and the second electrode.

The invention provides a heat treatment system (1000) comprising a heat treatment apparatus (1) and a product transport system (200), wherein the heat treatment apparatus (1) comprises (i) a duct (100) having a duct axis (110), wherein the duct (100) is configured for holding a liquid (2), and (ii) an RF heating zone (5) comprising a main electrode (410) and a first counter electrode (420) configured for functionally connecting to an RF generator (400) to generate during operation a first electric field (490) in the duct (100) between the main electrode (410) and the first counter electrode (420) parallel to the duct axis (110); the product transport system (200) comprises an electric field guiding element (440) comprising an electrically conductive material (401), wherein the electric field guiding element is configured to be electrically insulated from the electrodes (410, 420) during transport through the duct (100); and the product transport system (200) is configured to transport a product (60) and the electric field guiding element (440) through the duct (100).

The invention provides a heat treatment system (1000) comprising a heat treatment apparatus (1) and a product transport system (200), wherein the heat treatment apparatus (1) comprises (i) a duct (100) having a duct axis (110), wherein the duct (100) is configured for holding a liquid (2), and (ii) an RF heating zone (5) comprising a main electrode (410) and a first counter electrode (420) configured for functionally connecting to an RF generator (400) to generate during operation a first electric field (490) in the duct (100) between the main electrode (410) and the first counter electrode (420) parallel to the duct axis (110); the product transport system (200) comprises an electric field guiding element (440) comprising an electrically conductive material (401), wherein the electric field guiding element is configured to be electrically insulated from the electrodes (410, 420) during transport through the duct (100); and the product transport system (200) is configured to transport a product (60) and the electric field guiding element (440) through the duct (100).

An inductor assembly includes a fixture element having a central core and support structures coupled to and projecting outwardly from the central core, each of the support structures having an outer edge with a notched profile of indentations extending toward the central core, and a helical inductor having multiple turns, the turns being seated in the indentations of the at least two support structures. The support structures may be equidistantly spaced apart from one another about the central core by air gaps. The inductor assembly may be incorporated in an impedance matching network, and one or more impedance matching networks may be incorporated in a defrosting system. The impedance matching network may be a single-ended network or a double-ended network.

An inductor assembly includes a fixture element having a central core and support structures coupled to and projecting outwardly from the central core, each of the support structures having an outer edge with a notched profile of indentations extending toward the central core, and a helical inductor having multiple turns, the turns being seated in the indentations of the at least two support structures. The support structures may be equidistantly spaced apart from one another about the central core by air gaps. The inductor assembly may be incorporated in an impedance matching network, and one or more impedance matching networks may be incorporated in a defrosting system. The impedance matching network may be a single-ended network or a double-ended network.

A high-frequency heating apparatus according to the present disclosure includes a first electrode (11), a second electrode (12), a high-frequency power supply (30), a position adjuster (20), a detector (50), and a controller (60). The second electrode (12) is disposed facing the first electrode. The high-frequency power supply (30) supplies a high-frequency power to the first electrode. The position adjuster (20) adjusts a distance between the first electrode (11) and the second electrode (12). The detector (50) detects a reflected power from the first electrode (11) toward the high-frequency power supply (30). The controller (60) controls the position adjuster (20) based on the reflected power. In this embodiment, a heating target can be heated efficiently.

A high-frequency heating apparatus according to the present disclosure includes a first electrode (11), a second electrode (12), a high-frequency power supply (30), a position adjuster (20), a detector (50), and a controller (60). The second electrode (12) is disposed facing the first electrode. The high-frequency power supply (30) supplies a high-frequency power to the first electrode. The position adjuster (20) adjusts a distance between the first electrode (11) and the second electrode (12). The detector (50) detects a reflected power from the first electrode (11) toward the high-frequency power supply (30). The controller (60) controls the position adjuster (20) based on the reflected power. In this embodiment, a heating target can be heated efficiently.