Voltage application device includes voltage application circuit. Voltage application circuit applies a voltage to load including discharge electrode that holds liquid, voltage application circuit generating discharge in discharge electrode. During a drive period, voltage application circuit periodically changes a magnitude of the voltage applied to load at a drive frequency within a predetermined range including a resonance frequency of liquid, voltage application circuit mechanically vibrating liquid.

An air motor, a rotary atomizing head provided on a front side of the air motor to be rotatable by the air motor, external electrode units provided in a periphery of the rotary atomizing head, and a high-voltage applying unit that applies a high voltage to the external electrode units to indirectly charge paint particles atomized from the rotary atomizing head with the high voltage. A film cover is provided to be formed with a resin material in a film shape for covering an outer peripheral side of the air motor. The film cover includes a cylindrical rear cover that covers the rear side from the external electrode units and a cylindrical front cover that is mounted to the front side of the rear cover to cover the front side from the external electrode units.

An air motor, a rotary atomizing head provided on a front side of the air motor to be rotatable by the air motor, external electrode units provided in a periphery of the rotary atomizing head, and a high-voltage applying unit that applies a high voltage to the external electrode units to indirectly charge paint particles atomized from the rotary atomizing head with the high voltage. A film cover is provided to be formed with a resin material in a film shape for covering an outer peripheral side of the air motor. The film cover includes a cylindrical rear cover that covers the rear side from the external electrode units and a cylindrical front cover that is mounted to the front side of the rear cover to cover the front side from the external electrode units.

A chamber (1) and an air conduit (7) connecting a liquid surface retaining hole (5) with an air hole (6) for supplying air from the outside of an electrostatic atomizer (50) to the chamber (1) are provided. When the liquid surface retaining hole (5) is blocked, the liquid supply from a liquid supplying section (3) to the chamber (1) will be stopped. The air conduit (7) has bent sections (8), and a space (10) for holding the liquid is formed in the air conduit (7).

A chamber (1) and an air conduit (7) connecting a liquid surface retaining hole (5) with an air hole (6) for supplying air from the outside of an electrostatic atomizer (50) to the chamber (1) are provided. When the liquid surface retaining hole (5) is blocked, the liquid supply from a liquid supplying section (3) to the chamber (1) will be stopped. The air conduit (7) has bent sections (8), and a space (10) for holding the liquid is formed in the air conduit (7).

Embodiments of the invention are directed to a thin film fabricating apparatus which may be employed in mass production and may stably provide a uniform nano-order layer. An exemplary embodiment of a thin film fabricating apparatus includes: an electrode bath which contains a thin film-forming material; a plurality of needle electrodes disposed in the electrode bath; a plurality of ring electrodes disposed on the electrode bath at positions corresponding to the needle electrodes; and a substrate stand disposed opposite to the needle electrodes and the ring electrodes, where the substrate stand holds the substrate, on which a thin film is to be formed.

Embodiments of the invention are directed to a thin film fabricating apparatus which may be employed in mass production and may stably provide a uniform nano-order layer. An exemplary embodiment of a thin film fabricating apparatus includes: an electrode bath which contains a thin film-forming material; a plurality of needle electrodes disposed in the electrode bath; a plurality of ring electrodes disposed on the electrode bath at positions corresponding to the needle electrodes; and a substrate stand disposed opposite to the needle electrodes and the ring electrodes, where the substrate stand holds the substrate, on which a thin film is to be formed.

A device for coating a metal strip substrate includes a guiding apparatus for guiding the strip substrate along a movement path. A first coating apparatus coats a first main side of the strip substrate with an electrostatically charged coating powder which is in a fluidized state. The first coating apparatus is arranged under a first path section of the movement path. A second coating apparatus coats a second main side of the strip substrate with an electrostatically charged coating powder which is in a fluidized state. A redirecting unit redirects the strip substrate between the first and the second coating apparatus in such a way that the strip substrate in a second path section travels oppositely to the strip substrate in the first path section. The second coating apparatus is arranged at least partly geodetically under the second path section.

A rotary atomizing head (4) is mounted on a front end side of an air motor (3). A shaping air ring (9) with air spout holes (10, 11) formed therein is provided on the rear side of the rotary atomizing head (4). The shaping air ring (9) is formed of a conductive material and is connected to ground. External electrode units (13) are provided in the periphery of the rotary atomizing head (4). A film cover (17) made of an insulating material is provided to cover an outer peripheral side of the air motor (3). A semi conductive member (21) is replaceably mounted to an adaptor (16) provided on an outer peripheral side of the shaping air ring (9). A rear end part (21B) of the semi conductive member (21) is made in contact with a front end part (19D) of the film cover (17). A front end part (21C) of the semi conductive member (21) is made in contact with the shaping air ring (9).

A rotary atomizing head (4) is mounted on a front end side of an air motor (3). A shaping air ring (9) with air spout holes (10, 11) formed therein is provided on the rear side of the rotary atomizing head (4). The shaping air ring (9) is formed of a conductive material and is connected to ground. External electrode units (13) are provided in the periphery of the rotary atomizing head (4). A film cover (17) made of an insulating material is provided to cover an outer peripheral side of the air motor (3). A semi conductive member (21) is replaceably mounted to an adaptor (16) provided on an outer peripheral side of the shaping air ring (9). A rear end part (21B) of the semi conductive member (21) is made in contact with a front end part (19D) of the film cover (17). A front end part (21C) of the semi conductive member (21) is made in contact with the shaping air ring (9).