A liner machine for applying a sealing compound to a can end or lid. The liner machine includes a motor drive dual turret system. The turret system is installed at the top of a table or platform surface and two turrets rotate in opposition directions from one another, simultaneously or independently at same or different times. Each turret includes a plurality of workstations which extend out from each turret facing away from each other. The workstations receive an individual lid, which is delivered via a starwheel from a downstacker to each turret system. Each rotates in a direction that is opposite the direction that its respective turret system rotates, and in a direction that is opposite the direction that the other starwheel rotates. Sealant injectors in the turret systems apply sealant to each lid as the lids rotate around each turret system.

Impregnation plant for internally hollow cylindrical components (stators) of electric motors including working stations arranged linearly and sequentially, managed and controlled by central processing unit; and a plurality of motor-driven elements to impart rotatory motion, in both directions of rotation, and tilting motion, in both directions respective to a predefined plane, to each component mounted onto a respective support device when such support device is inserted into the plant working stations. Each support device has a spring collet in turn has blocks clamping the component onto the inner diameter of its respective cylindrical body. Each spring collet entirely crosses the component cylindrical body to rest on both of its respective circumferential ends. An impregnation method for electric motor components using the impregnation plant, wherein the component is rotatable in both directions about a support device predefined axis, and tiltable respective to a predefined plane of such support device.

A coating assembly for coating a plurality of substrates. The coating assembly includes a chamber. At least one target is disposed in the chamber and includes a coating material. At least one power supply is connected to the target. At least one support fixture is disposed in the chamber. The at least one support fixture includes a base having a plurality of recesses formed in an upper surface of the base. A first mounting component has a plurality of slots. The first mounting component is positioned on the upper surface of the base wherein at least some of the plurality of recesses are in registry with corresponding ones of the plurality of slots to define a plurality of cavities, each of the plurality of cavities configured to hold at least one of the plurality of substrates to be coated.

Aspects herein relate to coating apparatus and methods for coating medical devices. In an embodiment, a coating system is included having a valve, a fluid supply reservoir in fluid communication with the valve, a reciprocating positive displacement pump in fluid communication with the valve, and a fluid applicator in fluid communication with the three-way valve. The valve can be configured to assume a first fluid transport state and a second fluid transport state, wherein the valve provides fluid communication between the fluid supply reservoir and the reciprocating positive displacement pump when in the first fluid transport state for filling of the reciprocating positive displacement pump, and wherein the valve provides fluid communication between the reciprocating positive displacement pump and the fluid applicator when in the second fluid transport state for applying a coating suspension to a medical device surface. Other embodiments are also included herein.

A mechanism for applying a predetermined pattern of material onto an elongate tubular substrate includes a first motor, an engagement member rotatable by the first motor and configured to reversibly grasp an elongate member, such that rotation of the first motor rotates the elongate member around its longitudinal axis, a fluid dispenser configured to dispense a fluid having a first, flowable state, the fluid dispenser including an elongate dispensing conduit having a distal end having an orifice, the orifice configured to be placed adjacent a surface of the elongate member, a second motor configured to move at least one of the elongate member or the elongate dispensing conduit such that the orifice changes its relative orientation along the longitudinal axis of the elongate member, and wherein the distal end of the elongate dispensing conduit is configured to apply a bias on the surface of the elongate member.

An adhesive dispenser includes a support structure, a valve body that is mounted to the support structure and is configured to receive at least first and second adhesive materials, and a nozzle assembly that is connected to the valve body. The nozzle assembly includes a rigid tube that extends from the valve body to a tube end, and a mixing insert that is received within the tube and extends to an insert end. The mixing insert is configured to receive the first and second adhesive materials from the valve body for intermixing upstream from the insert end. The dispenser further includes a nozzle that is supported relative to the support structure and arranged about the tube end and the insert end. The nozzle has an opening at a terminal end, and a shaped aperture adjoins the opening. The nozzle is configured to dispense intermixed adhesive through the opening and aperture onto a component.

A lubricant/sealer dispenser is disclosed for a component press-in system that includes a pressurized lubricant/sealer reservoir filled with lubricant/sealer. A nozzle is supplied with lubricant/sealer from the reservoir and includes an offset tip formed of PTFE that is enclosed in a steel tube. A controller controls a motor that rotates the nozzle within an opening in a part at a selected depth. The motor rotates the nozzle about a fixed axis and follows an inner surface of the opening as the part is moved by a robot relative to the nozzle in a selected pattern. The nozzle applies the lubricant/sealer by applying the lubricant/sealer onto the inner surface of the opening.

A system and method for coating an expandable member of a medical device comprising a support structure to support the expandable member and a dispenser positioned with at least one outlet proximate a surface of an expandable member. A drive assembly establishes relative movement between the at least one outlet and the surface of the expandable member to apply fluid on the surface of the expandable member along a coating path. A guide maintains a substantially fixed distance between the at least one outlet and the surface of the expandable member during relative movement therebetween by displacing the expandable member relative to the at least one outlet.

A method and apparatus for applying sealant. The apparatus may comprise a shaping portion, a centering portion, and a support system. The shaping portion may have a cavity configured to receive a fastener system and receive a sealant. The centering portion may have a channel configured to position the shaping portion in a desired position around the fastener system when the fastener system is received in the cavity. The support system may be configured to maintain the desired position of the apparatus.

The disclosure relates to a coating device for edge-coating a panel with a coating medium, the device comprising at least one medium line, for guiding a coating medium, which comprises an inlet and an outlet, wherein the medium line comprises a recess for introducing a panel into a coating-medium stream, and wherein the medium line and the recess are designed such that the coating medium can be applied to the edge of the panel by means of suction in the flow direction of the medium. The present disclosure also relates to a coating system for edge-coating a panel with a coating medium.