A light assembly coupled to a spray gun for spraying electrostatically charged coating material is disclosed. The spray gun includes a gun body comprising a barrel, a nozzle assembly extending from the barrel in a longitudinal direction, a voltage multiplier, and an actuator assembly configured to transition the voltage multiplier between an activated state and a deactivated state. The light assembly includes a light and circuitry electrically connected to the light. The circuitry is configured to supply electrical energy inductively obtained by the circuitry to the light when the voltage multiplier is in the activated state. The light assembly can also include a housing, a lens cover releasably attached to the housing, and a control member for changing a characteristic of the light.

A light assembly coupled to a spray gun for spraying electrostatically charged coating material is disclosed. The spray gun includes a gun body comprising a barrel, a nozzle assembly extending from the barrel in a longitudinal direction, a voltage multiplier, and an actuator assembly configured to transition the voltage multiplier between an activated state and a deactivated state. The light assembly includes a light and circuitry electrically connected to the light. The circuitry is configured to supply electrical energy inductively obtained by the circuitry to the light when the voltage multiplier is in the activated state. The light assembly can also include a housing, a lens cover releasably attached to the housing, and a control member for changing a characteristic of the light.

Provided is a visual insulating spray lance for live working. A liquid guide tube and an air tube in a hollow operating rod are communicated with an inlet end of a spray nozzle; the operating rod is connected to a connecting rod and a display respectively through a fastener; a video optical transceiver fixedly arranged on the connecting rod is connected to the display through an optical fiber; the optical fiber is connected to an optical receiver, the optical receiver is connected to a chip for a video signal processor, the chip for a video signal processor is connected to a power divider having two output interfaces respectively connected to a display screen and a 4G communication module; a battery is connected to the optical receiver, the chip for a video signal processor, the power divider, the display screen, the 4G communication module, and a global positioning system (GPS) module.

Provided is a visual insulating spray lance for live working. A liquid guide tube and an air tube in a hollow operating rod are communicated with an inlet end of a spray nozzle; the operating rod is connected to a connecting rod and a display respectively through a fastener; a video optical transceiver fixedly arranged on the connecting rod is connected to the display through an optical fiber; the optical fiber is connected to an optical receiver, the optical receiver is connected to a chip for a video signal processor, the chip for a video signal processor is connected to a power divider having two output interfaces respectively connected to a display screen and a 4G communication module; a battery is connected to the optical receiver, the chip for a video signal processor, the power divider, the display screen, the 4G communication module, and a global positioning system (GPS) module.

A method and apparatus for fabricating multifunction membranes comprising cross-aligned nanofiber in an electrospinning device, the method comprising providing a multiple segment collector including at least a first segment, a second segment, and an intermediate segment to collectively present an elongated cylindrical structure; electrically charging an edge conductor circumferentially resident on the first segment and on the second segment; rotating the elongated cylindrical structure on a drive unit around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded and a charged electrode is positioned opposite a fiber emitter; and repeating the process multiple times to form layers of nanofibers encapsulating agents of interest.

A method and apparatus for fabricating multifunction membranes comprising cross-aligned nanofiber in an electrospinning device, the method comprising providing a multiple segment collector including at least a first segment, a second segment, and an intermediate segment to collectively present an elongated cylindrical structure; electrically charging an edge conductor circumferentially resident on the first segment and on the second segment; rotating the elongated cylindrical structure on a drive unit around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded and a charged electrode is positioned opposite a fiber emitter; and repeating the process multiple times to form layers of nanofibers encapsulating agents of interest.

The present invention relates to a method for treating skin, comprising the following step A) and then step B): A) physically or chemically treating an epidermis of the skin; and B) forming a film containing a fiber deposit on the skin which has been subjected to the step A). When the above step B) is applied to the skin after the conventional step A), skin conditions such as inflammation, redness, and swelling caused by the step A) are alleviated, these conditions disappear more quickly, and the quality of life (QOL) of persons who have undergone the cosmetic or dermatological treatment is significantly improved.

An electrostatic fluid delivery system is configured to deliver fluid, such as a disinfectant fluid, onto a surface by electrically charging the fluid and forming the fluid into a mist, fog, plume, or spray that can be directed onto a surface, such as a surface to be cleaned. The system atomizes the fluid using a high-pressure fluid stream and passes the fluid through an electrode of a nozzle assembly to charge droplets of the atomized fluid.

An apparatus is provided for generating water droplets. The apparatus includes: a condensation rod for condensing water vapor in air surrounding the condensation rod on the condensation rod; a cooling device being in contact with the condensation rod for cooling the condensation rod; a discharge electrode group including a first electrode and a second electrode cooperating with each other, the first electrode and the second electrode being disposed laterally, and the first electrode and the second electrode are respectively disposed on both sides of the condensation rod; and a high voltage power supply for applying a high voltage to the discharge electrode group to generate a high voltage corona between the first electrode and the second electrode; where the discharge electrode group applies the high voltage corona to the condensation rod, so that condensed water on the condensation rod is excited by the high voltage corona to form atomized water droplets.

A film forming device 10 including a distance measurement unit 30 for measuring the distance between the skin S and the device 10, a distance decision unit 31 for deciding whether the distance measured by the distance measurement unit 30 is proper for electrostatic spraying, and a distance notification unit 32 for notifying a user of the decision by the distance decision unit 31. The film forming device 10 is of hand-held type small enough and configured to be held by the user's hand. The device 10 preferably includes an angle measurement unit 42 for measuring the angle between the electrostatic spray direction and the skin S.