An electrostatic spray apparatus includes an electrostatic spray gun having a first external surface and a second external surface. A first electrode is disposed on the first external surface and is configured to ionize a material and to generate a first electrical field between the first electrode and a grounded object. A second electrode is disposed on the second external surface of the apparatus and is configured to generate a second electric field between the second electrode and the grounded object.

A mounting configuration for an electrostatic spray gun (100) includes a probe having a first non-conductive body encasing a first conductive element and a probe mount extending from the electrostatic spray gun with a second non-conductive body encasing a second conductive element. The mounting configuration includes a first elastomeric ring (140) disposed about the second non-conductive body and configured to interface with the first non-conductive body. The first elastomeric ring (140) is configured to exert a force on the first non-conductive body to bias the first non-conductive body away from the electrostatic spray gun (100) such that the probe is secured in a home position. A pin (128) extending from one of the first non-conductive body and the second non-conductive body is seated in a notch (138) formed in the other one of the first non-conductive body and the second non-conductive body.

An ionising device is described comprising a tubular bulb of electrically insulating or dielectric material extending along a longitudinal reference axis and having the two opposite longitudinal terminal ends and open, a tubular cathode engaged in the bulb, a tubular anode fitted onto the bulb, a pair of covers coupled to a relative end of said bulb so as to hermetically close it, and a conductive electrode comprising a stem extending into said bulb, and a plurality of conductive crowns which are fitted onto the stem at predetermined distances from each other and are suitable to exert an elastic compression on the tubular cathode against the inner surface of the bulb.

Provided is a hand-held type electrostatic spray device (1) spraying an electrically charged liquid, the electrostatic spray device (1) comprising: a voltage source; a needle-shaped electrode (53: a base electrode) for electrically charging the liquid to which a voltage is applied from the voltage source and which includes a linear tip portion; a second bottom portion (32: an additional electrode) of a second electrode member (3) to which a voltage is applied from the voltage source; and a conductor (6) which is electrically isolated from the second bottom portion (32) and the needle-shaped electrode (53) and is disposed on a spray side of the liquid from the second bottom portion (32), at least a part of the conductor (6) overlapping with the second bottom portion (32) in a direction orthogonal to a spray direction of the liquid.

Effective component generation device includes internal component and case. Internal components include discharger that generates an effective component. Case is formed in a box shape having discharge port through which an effective component is discharged, and houses internal components. Case includes metal body including a bottom plate and peripheral walls surrounding at least discharger in internal component. Metal body has seamless portion at a corner portion between two surfaces of adjacent peripheral walls oriented in different directions. As a result, there is provided effective component generation device capable of suppressing electromagnetic noise radiated to the outside of case and reducing an influence of electromagnetic noise to the outside.

A system includes an electrostatic tool having a cascade that includes electrical components configured to convert a first voltage from an incoming alternating current into an outgoing second voltage at a direct current and a shell configured to cover the electrical components. The shell radially conforms to the electrical components.

An exemplary embodiment of the present invention provides an electrostatic metal porous body forming apparatus including: a transfer module transferring a porous body substrate; and a coating module coating a metal powder on the porous body substrate, wherein the transfer module includes a substrate supporter fixing the porous body substrate while the porous body substrate is transferred, and wherein the coating module includes: an electrifier including a first electrode electrifying the metal powder, a second electrode facing the first electrode, a first power supplier connected with the first electrode supplying electricity to the first electrode, and a second power supplier connected with the second electrode supplying electricity electrified with an opposite charge to a charge caused by the electrification of the first electrode to the second electrode, and generating a pulse type of voltage; and a metal powder supplier including a metal powder vessel storing the metal powder therein and supplying the metal powder to the outside, and an outlet separately disposed above or below the porous body substrate injecting the metal powder, and transferring or injecting the metal powder that is electrified and coated by the electrifier.

A mounting configuration for an electrostatic spray gun includes a probe having a first non-conductive body encasing a first conductive element and a probe mount extending from the electrostatic spray gun with a second non-conductive body encasing a second conductive element. The mounting configuration includes a first elastomeric ring disposed about the second non-conductive body and configured to interface with the first non-conductive body. The first elastomeric ring is configured to exert a force on the first non-conductive body to bias the first non-conductive body away from the electrostatic spray gun such that the probe is secured in a home position. A pin extending from one of the first non-conductive body and the second non-conductive body is seated in a notch formed in the other one of the first non-conductive body and the second non-conductive body

Voltage application device includes voltage application circuit. Voltage application circuit causes discharge electrode to generate a discharge by applying an application voltage to load that includes discharge electrode holding liquid. Voltage application circuit periodically changes a magnitude of the application voltage to generate a discharge intermittently. Voltage application circuit applies a maintaining voltage to load for suppressing contraction of liquid in addition to the application voltage during an intermittent period from a discharge to a next discharge.

A plasma nano mist generation device includes: a discharge tube into which a solution is injected, the discharge tube being configured by a dielectric material; a liquid feeding unit configured to feed the solution into the discharge tube; an electrode provided in the discharge tube; a voltage application unit configured to apply a voltage to the electrode; a ground electrode provided on a side of a distal end of the electrode and on an outer periphery of the discharge tube, the ground electrode being grounded in the device itself; and a controller configured to control the liquid feeding unit and the voltage application unit such that the solution is fed to the discharge tube and a voltage is applied to the electrode in order to generate dielectric barrier discharge on the side of the distal end of the electrode to generate plasma nano mist.