A pulsation dampener for a dispensing system comprising a housing, a diaphragm comprising at least one fluoropolymer layer, the diaphragm dividing the housing into a first compartment and a second compartment, an inlet port and an outlet port each in fluid communication with the first compartment thereby providing a flow path for a liquid to enter the first compartment via the first inlet port and exit the first compartment via the outlet port, and at least one gas disposed within the second compartment, the at least one gas having a kinetic diameter of 0.36 nm or greater, wherein the fluoropolymer of the at least one fluoropolymer layer and the at least one gas are selected such that a gas transmittance rate of the at least one gas through the diaphragm is from 0 mbar*L/second to 1*10.sup.−5 mbar*L/second.

There is provided that an imprint apparatus that forms a pattern on a substrate by curing an imprint material in a state in which a mold and the imprint material on the substrate are in contact with each other, the apparatus including a control unit configured to control a movement of a stage configured to hold the substrate and the supplying of a gas by a gas supplying unit, wherein the control unit removes charges from the mold by starting the supplying of the gas by the gas supplying unit before starting to move the stage below a dispenser after the mold and the cured imprint material are separated, and making a peripheral member face the mold via the gas during the movement of the stage.

There is provided that an imprint apparatus that forms a pattern on a substrate by curing an imprint material in a state in which a mold and the imprint material on the substrate are in contact with each other, the apparatus including a control unit configured to control a movement of a stage configured to hold the substrate and the supplying of a gas by a gas supplying unit, wherein the control unit removes charges from the mold by starting the supplying of the gas by the gas supplying unit before starting to move the stage below a dispenser after the mold and the cured imprint material are separated, and making a peripheral member face the mold via the gas during the movement of the stage.

A device for a lacquer transfer includes a transfer roller mounted at and rotatable relative to a frame. The roller includes a cylindrical support-body, first ring-element, second ring-element, and a tire including a middle-section forming a circumferential outer contact surface with depressions, the roller configured to roll with the outer contract surface on a work surface of a workpiece for transferring lacquer from the outer contact surface and the depressions to the work surface. The tire includes two annular end-sections attached to a cylindrical outer shell of the support-body resulting in two axially separated and circumferentially extending connections, the tire, connections, and outer shell of the support-body being fluid-tight. The first and second ring-elements are in the first cavity seated on the support-body at a distance in an axial direction of the roller from one another and the middle-section of the tire between the first and second ring-elements is prestrained in the axial direction.

This application relates to an apparatus for producing a graphene film with a thermal manipulation function. The apparatus includes a filter cup, a filter flask, a vacuum pump, a fixing clamp, and a laser. The fixing clamp is configured to clamp a first filter membrane and a second filter membrane. The laser is configured to irradiate the first filter membrane. The first filter membrane and the second filter membrane are arranged stackedly. The filter cup and the filter flask are in snap fit up and down. The first filter membrane and the second filter membrane are arranged between the filter cup and the filter flask. The vacuum pump is in communication with the filter flask. This application also provides a method for producing the graphene film with a thermal manipulation function.

This application relates to an apparatus for producing a graphene film with a thermal manipulation function. The apparatus includes a filter cup, a filter flask, a vacuum pump, a fixing clamp, and a laser. The fixing clamp is configured to clamp a first filter membrane and a second filter membrane. The laser is configured to irradiate the first filter membrane. The first filter membrane and the second filter membrane are arranged stackedly. The filter cup and the filter flask are in snap fit up and down. The first filter membrane and the second filter membrane are arranged between the filter cup and the filter flask. The vacuum pump is in communication with the filter flask. This application also provides a method for producing the graphene film with a thermal manipulation function.

Provided are a cleaning cavity series for extrusion type coating, and a cleaning method. The cleaning cavity series for extrusion type coating includes a plurality of cleaning cavities, where the plurality of cleaning cavities form the cleaning cavity series, each of the plurality of cleaning cavities is provided with an inner cavity body, a cleaning cavity opening portion in communication with the inner cavity body is disposed on a side portion of each of the plurality of cleaning cavities, and cross-section outlines of the inner cavity bodies of the plurality of cleaning cavities are a series of curves with an equal chord length. The cleaning method includes: S1: evaluating an envelope line of a slurry that overflows from a lip portion of a coating head, and selecting one cleaning cavity from a cleaning cavity series to ensure that an enveloped area of the envelope line accounts for 30%-70% of the sectional area of an inner cavity body of the selected cleaning cavity; and S2: selecting a static cleaning method or a dynamic cleaning method to perform a cleaning operation on the coating head using the selected cleaning cavity from the cleaning cavity series. The cleaning cavity series for extrusion type coating, and the cleaning method using same have the advantages of having a simple structure, being convenient to apply, being low in implementation cost, and improving the cleaning effect, the coating quality and the production efficiency.

An applicator head for a vacuum coating system includes a manifold shell having opposing shell plates, each including a conduit attachment coupled to a shell aperture. An applicator manifold is affixed to each shell plate. Each applicator manifold includes two coupled manifold plates, with one including a manifold aperture, and each is affixed to the respective shell plate so that each manifold aperture aligns with the respective shell aperture. An applicator channel is formed between the manifold plates of each applicator manifold, and the applicator channel is fluidically coupled to the manifold aperture of each respective applicator manifold. Each applicator channel forms an applicator port at a leading edge of each respective applicator manifold, and each leading edge is configured to be complementary in shape to an edge of a workpiece to be coated. First and second face plates are disposed over the leading edges of the applicator manifolds.

Tooling for the coating of lips of a turbomachine rotor sector, comprising a support for a rotor sector, a centering plate adapted to be inserted into a rotor sector, said centering plate having a central housing, a tool, said tool comprising a centering arm, adapted to be inserted into the central housing of the centering plate, a torch, adapted to spray a ceramic material, a machining tool, said tooling being configured so as to position the tool relative to the rotor sector via the centering plate, and to simultaneously perform on the rotor sector a spraying of ceramic material and a machining on two distinct sectors of the lips.

Tooling for the coating of lips of a turbomachine rotor sector, comprising a support for a rotor sector, a centering plate adapted to be inserted into a rotor sector, said centering plate having a central housing, a tool, said tool comprising a centering arm, adapted to be inserted into the central housing of the centering plate, a torch, adapted to spray a ceramic material, a machining tool, said tooling being configured so as to position the tool relative to the rotor sector via the centering plate, and to simultaneously perform on the rotor sector a spraying of ceramic material and a machining on two distinct sectors of the lips.