Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: An apparatus and a method for surface coating by means of grid control and plasma-initiated gas-phase polymerization. The method comprises: dividing a vacuum chamber into a discharging cavity (2) and a processing chamber (3) by using a metal grid mesh (1), the metal grid mesh (1) being insulated from the vacuum chamber; separately feeding carrier gas and monomer steam into the discharging cavity (2) and the processing chamber (3) through different pipes (4, 5), putting a substrate to be processed (11) in the processing chamber (3), and generating in the discharging cavity (2) plasma that continuously discharges; and applying pulse positive bias to the metal grid mesh (1), to release the plasma into the processing chamber (3) to initiate monomer polymerization.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Methods and associated systems for preparing a nano-protective coating are disclosed. The method includes (1) placing a substrate in a reaction chamber of a nano-coating preparation equipment; (2) introducing an inert gas, wherein the inert gas includes helium (He) and/or argon (Ar); (3) turning on a movement mechanism so that the substrate is moved in the reaction chamber; (4) introducing a first monomer vapor into the reaction chamber to achieve a vacuum degree of 30-300 mTorr; (5) turning on a plasma discharge for chemical vapor deposition; and (6) introducing a second monomer vapor into the reaction chamber to form an organosilicon nano-coating on a surface of the substrate.

Abstract: Methods and associated systems for preparing a nano-protective coating are disclosed. The method includes (1) placing a substrate in a reaction chamber of a nano-coating preparation equipment; (2) introducing an inert gas, wherein the inert gas includes helium (He) and/or argon (Ar); (3) turning on a movement mechanism so that the substrate is moved in the reaction chamber; (4) introducing a monomer vapor into the reaction chamber to achieve a vacuum degree of 30-300 mTorr; and (5) turning on a plasma discharge for chemical vapor deposition to form an organosilicon nano-coating on a surface of the substrate.

Abstract: A diffuser includes a cone body including an apex portion, a bottom portion, and a side edge portion. The apex portion forms a partial spherical surface, and the side edge portion is aspherical and is connected between the apex portion and the bottom portion. The apex portion satisfies: 2R/3?r?R, where r is a radius of curvature of the apex portion, and R is a radius of curvature of a spherical diaphragm of a tweeter speaker. A loudspeaker including a tweeter speaker and a diffuser is also provided.

Abstract: Methods and apparatus for preparing a protective coating are described. In one example aspect, an apparatus for preparing a protective coating includes a chamber, a substrate positioned within the chamber configured to hold at least a target object, an inlet pipe configured to direct a monomer vapor into the chamber, and one or more electrodes configured to perform a chemical vapor deposition process to produce a multi-layer coating. The chemical vapor deposition process comprises multiple cycles, each cycle comprising a pretreatment phase and a coating phase to produce a layer of the multi-layer coating.

Abstract: Methods and apparatus for preparing a protective coating are described. In one example aspect, a method for preparing a protective coating includes positioning one or more target objects into a chamber. The chamber comprises a movable substrate and one or more trays coupled to the movable substrate to hold the one or more target objects such that the one or more target objects are movable within the chamber. The method also includes adding a monomer vapor into the chamber and performing a chemical vapor deposition process that comprises at least one cycle, each including a pretreatment phase and a coating phase.

Abstract: A diffuser includes a cone body including an apex portion, a bottom portion, and a side edge portion. The apex portion forms a partial spherical surface, and the side edge portion is aspherical and is connected between the apex portion and the bottom portion. The apex portion satisfies: 2R/3?r?R, where r is a radius of curvature of the apex portion, and R is a radius of curvature of a spherical diaphragm of a tweeter speaker. A loudspeaker including a tweeter speaker and a diffuser is also provided.

Abstract: 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.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape to a central axis. A rotation rack may be operable to rotate about the central axis of the vacuum chamber. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber in a substantially symmetrical manner from the outer perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a polymeric multi-layer coating on surfaces of the one or more devices. Each layer may have a different composition of atoms to enhance the water resistance, corrosion resistance, and fiction resistance of the polymeric multi-layer coating.

Abstract: Introduced here is a plasma polymerization apparatus. Example embodiments include a reaction chamber in a shape substantially symmetrical to a central axis. Some examples further include a rotation rack in the reaction chamber. The rotation rack may be operable to rotate relative to the reaction chamber about the central axis of the reaction chamber. Examples may further include two reactive species discharge mechanisms positioned around a perimeter of the reaction chamber and configured to disperse reactive species into the reaction chamber in a substantially symmetrical manner from the outer perimeter of the reaction chamber toward the central axis of the reaction chamber, such that the reactive species form a polymeric coating on surfaces of the one or more substrates during said dispersion of the reactive species, and a collecting tube positioned along the central axis of the reaction chamber and having an air pressure lower than the reaction chamber.

Abstract: Introduced here is a plasma polymerization apparatus and process. Example embodiments include a vacuum chamber in a substantially symmetrical shape relative to a central axis. A primary rotation shaft may be operable to rotate about the central axis of the vacuum chamber and a secondary rotation shaft may be operable to rotate about a secondary axis distal to the central axis. The primary and secondary rotation shafts may be mechanically connected, and one or more devices may be secured on a platform that rotates along both shafts. Additionally, reactive species discharge mechanisms positioned around a perimeter of the vacuum chamber may be configured to disperse reactive species into the vacuum chamber. The reactive species may form a uniform polymeric multi-layer coating on the surface of the one or more devices.

Abstract: 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.

Abstract: Introduced here is a plasma polymerization apparatus. Example embodiments include a reaction chamber in a shape substantially symmetrical to a central axis. Some examples further include a rotation rack in the reaction chamber. The rotation rack may be operable to rotate relative to the reaction chamber about the central axis of the reaction chamber. Examples may further include reactive species discharge mechanisms positioned around a perimeter of the reaction chamber and configured to disperse reactive species into the reaction chamber in a substantially symmetrical manner from the outer perimeter of the reaction chamber toward the central axis of the reaction chamber, such that the reactive species form a polymeric coating on surfaces of the one or more substrates during said dispersion of the reactive species, and a collecting tube positioned along the central axis of the reaction chamber and having an air pressure lower than the reaction chamber.

Abstract: An apparatus and a method for surface coating by means of grid control and plasma-initiated gas-phase polymerization. The method comprises: dividing a vacuum chamber into a discharging cavity and a processing chamber by using a metal grid mesh, the metal grid mesh being insulated from the vacuum chamber; separately feeding carrier gas and monomer steam into the discharging cavity and the processing chamber through different pipes, putting a substrate to be processed in the processing chamber, and generating in the discharging cavity plasma that continuously discharges; and applying pulse positive bias to the metal grid mesh, to release the plasma into the processing chamber to initiate monomer polymerization.