The electrospray device comprises a sprayer comprising a sprayer body and nozzle, and a partition positioned vertically and coaxially with the sprayer. The sprayer body is provided with a swirl generator for generating a swirling air stream, and a power supply connected between the nozzle and the partition, to apply voltage to the nozzle and the partition. The electrospray device may be part of a fluidized bed apparatus comprising a product container, a lower plenum base, an air distribution plate resided therebetween. When the power supply applies voltage in opposite polarities to the nozzle and the partition, the fluidized bed apparatus is used for coating particles; and when the power supply applies voltage of the same, the fluidized bed apparatus is used for spray-drying a solution. The electrospray device uses an electromagnetic hydrodynamic method to improve the performance of the fluidized bed apparatus and optimize the process of product.

Provided is an electrostatic spraying device capable of spraying liquid, such as paint, onto a sprayed object in a stable manner. The electrostatic spraying device of the invention releases liquid in an electrically-charged state from a nozzle using an electrostatic force generated by voltage application and thus sprays the liquid onto a sprayed object. The electrostatic spraying device comprises a nozzle head provided with the nozzle comprising a plurality of nozzles made of conductive or semiconductive material and a voltage application device configured to apply voltage between the nozzles and a heteropolar portion (sprayed object) that is heteropolar to the nozzles and thus generate the electrostatic force. The nozzles are so arranged that distance between axes L of at least adjacent nozzles increases with increasing distance from the nozzle head.

Provided is an electrostatic spraying device capable of spraying liquid, such as paint, onto a sprayed object in a stable manner. The electrostatic spraying device of the invention releases liquid in an electrically-charged state from a nozzle using an electrostatic force generated by voltage application and thus sprays the liquid onto a sprayed object. The electrostatic spraying device comprises a nozzle head provided with the nozzle comprising a plurality of nozzles made of conductive or semiconductive material and a voltage application device configured to apply voltage between the nozzles and a heteropolar portion (sprayed object) that is heteropolar to the nozzles and thus generate the electrostatic force. The nozzles are so arranged that distance between axes L of at least adjacent nozzles increases with increasing distance from the nozzle head.

Provided are a pressure sensitive adhesive sheet including, on a substrate, a resin layer containing a resin which is a resin layer containing a resin part (X) containing a resin as a main component and a particle part (Y) consisting of fine particles, at least a surface () of the resin layer on the side opposite to the side thereof on which the substrate is provided, having pressure sensitive adhesiveness, wherein a bending stress coefficient k in the MD direction of the substrate is 20 N.Math.mm or less, a 10% elongation strength in the MD direction thereof is 260 N/15 mm or less, and concave portions satisfying specified requirements are included on the surface () of the resin layer; and a method for producing the pressure sensitive adhesive sheet.

Provided are a pressure sensitive adhesive sheet including, on a substrate, a resin layer containing a resin which is a resin layer containing a resin part (X) containing a resin as a main component and a particle part (Y) consisting of fine particles, at least a surface () of the resin layer on the side opposite to the side thereof on which the substrate is provided, having pressure sensitive adhesiveness, wherein a bending stress coefficient k in the MD direction of the substrate is 20 N.Math.mm or less, a 10% elongation strength in the MD direction thereof is 260 N/15 mm or less, and concave portions satisfying specified requirements are included on the surface () of the resin layer; and a method for producing the pressure sensitive adhesive sheet.

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 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.

The invention relates to a control circuit for protecting an electrostatic spray-coating apparatus, which has a high-voltage supply, against spark discharge. The control circuit has a disconnection device for automatically disconnecting the high-voltage supply, and has a device for detecting abnormal operation of the high-voltage supply. The device for detecting abnormal operation of the high-voltage supply is designed to monitor at least one parameter which is characteristic of the operation of the high-voltage supply, and to output a corresponding disconnection signal to the disconnection device when the at least one parameter which is characteristic of the operation of the high-voltage supply exceeds or falls below a predefined or predefinable limit value.

A multi-source low-power low-temperature plasma polymerized coating device and method belong to the technical field of plasma. In the device, a plurality of discharge cavities are mounted on the wall of a main vacuum chamber; a plane grounding grid mesh and a porous electrode plate are mounted in each discharge cavity; and the porous electrode plate is parallel to the grid mesh, keeps a gap with the grid mesh and is connected with a low-power high-frequency power source. A carrier gas pipeline and a monomer steam pipeline are respectively connected to each discharge cavity. To-be-treated base material is placed in the main vacuum chamber. The vacuum pump is started to feed carrier gas and monomer steam. The wall of the discharge cavity is discharged by the porous electrode plate; the monomer steam is polymerized; and the polymerisate passes through small holes and the grid mesh successively in the porous electrode plate to enter the vacuum chamber and deposit on the surface of the base material to form a polymer coating. The device of the present invention has the advantages of even spatial distribution of plasma, good quality uniformity of products under batch treatment, low plasma energy and density, difficult in excessively destroying a chemical monomer structure and good quality of the formed polymer coating.

A multi-source low-power low-temperature plasma polymerized coating device and method belong to the technical field of plasma. In the device, a plurality of discharge cavities are mounted on the wall of a main vacuum chamber; a plane grounding grid mesh and a porous electrode plate are mounted in each discharge cavity; and the porous electrode plate is parallel to the grid mesh, keeps a gap with the grid mesh and is connected with a low-power high-frequency power source. A carrier gas pipeline and a monomer steam pipeline are respectively connected to each discharge cavity. To-be-treated base material is placed in the main vacuum chamber. The vacuum pump is started to feed carrier gas and monomer steam. The wall of the discharge cavity is discharged by the porous electrode plate; the monomer steam is polymerized; and the polymerisate passes through small holes and the grid mesh successively in the porous electrode plate to enter the vacuum chamber and deposit on the surface of the base material to form a polymer coating. The device of the present invention has the advantages of even spatial distribution of plasma, good quality uniformity of products under batch treatment, low plasma energy and density, difficult in excessively destroying a chemical monomer structure and good quality of the formed polymer coating.