A combined mass airflow sensor and hydrocarbon trap is provided for absorbing evaporative hydrocarbon emissions from an air intake duct of an internal combustion engine. The combined mass airflow sensor and hydrocarbon trap comprises a duct that supports a hydrocarbon absorbing sheet in an unfolded configuration within a housing. The duct communicates an airstream from an air filter to the air intake duct during operation of the internal combustion engine. An opening in the housing receives a mass airflow sensor into the duct, such that the mass airflow sensor is disposed within the airstream. Guide vanes extending across the duct reduce air turbulence within the airstream passing by the mass airflow sensor. Ports disposed along the duct allow the evaporative hydrocarbon emissions to be drawn into the interior and arrested by the hydrocarbon absorbing sheet when the internal combustion engine is not operating.

An improved cathodic arc source and method of DLC film deposition with a carbon containing directional-jet plasma flow produced inside of cylindrical graphite cavity with depth of the cavity approximately equal to the cathode diameter. The generated carbon plasma expands through the orifice into ambient vacuum resulting in plasma flow strong self-constriction. The method represents a repetitive process that includes two steps: the described above plasma generation/deposition step that alternates with a recovery step. This step provides periodical removal of excessive amount of carbon accumulated on the cavity wall by motion of the cathode rod inside of the cavity in direction of the orifice. The cathode rod protrudes above the orifice, and moves back to the initial cathode tip position. The said steps periodically can be reproduced until the film with target thickness is deposited. Technical advantages include the film hardness, density, and transparency improvement, high reproducibility, long duration operation, and particulate reduction.

A substrate film forming machine table and a usage method. The substrate film forming machine table comprises: a first substrate bearing inlet and outlet chamber; a second substrate bearing inlet and outlet chamber; a film forming chamber; an intermediate chamber; a pump set connected to the first substrate bearing inlet and outlet chamber; a second pump connected to the intermediate chamber; a third pump connected to the film forming chamber and the second substrate bearing inlet and outlet chamber; at least one backup pump, which is provided to connect to the film forming chamber and the second substrate bearing inlet and outlet chamber so as to extract air from the film forming chamber and the second substrate bearing inlet and outlet chamber when the third pump is damaged; or, connecting to the intermediate chamber so as to extract air from the intermediate chamber when the second pump is damaged.

Embodiments of the present disclosure generally relate to optical devices. More specifically, embodiments described herein relate to a system and method of forming an optical device film. In an embodiment, a method is provided for positioning a substrate in a pre-cleaning chamber disposed in a cluster processing system and pre-cleaning the substrate to remove a native oxide layer from one or more surfaces of the substrate. The substrate is then transferred in an air free state to a deposition chamber disposed in the cluster processing system for forming an optical device film layer on the substrate.

There is provided a substrate processing system comprising: a plurality of transfer modules having transfer mechanisms configured to transfer substrates; and a plurality of process modules connected to the plurality of transfer modules. The transfer mechanisms of the plurality of transfer modules transfer a plurality of substrates sequentially and serially to the plurality of process modules, and each of the plurality of transfer modules has an aligner configured to align a substrate when transferring the substrate to the process module connected to a relevant transfer module.

Apparatus and methods for flipping substrates in vacuum between PVD sputtering of each side for increasing throughput are provided herein. In some embodiments disclosed herein, a module of a processing system for flipping a substrate in vacuum is provided. The module includes a clamp assembly for securing the substrate, a first motor assembly coupled to the clamp assembly for rotating the clamp assembly, and a second motor assembly coupled to the first motor assembly for raising and lowering the first motor assembly and the clamp assembly.

Coating processes for vacuum chamber arrangements and apparatus thereof are herein disclosed. In some aspects, a coating process may include coating at least one workpiece using a vacuum chamber arrangement. The vacuum chamber arrangement may include a vacuum chamber, a substrate holding arrangement, an additional substrate holding arrangement, one or more bearings, a supply hose and an additional supply hose. The vacuum chamber may include a lock chamber, an additional lock chamber, a heating chamber, an additional heating chamber, and a coating chamber. The one or more bearings may support the substrate holding arrangement in such a way that it can be moved between the lock chamber and the coating chamber. The one or more bearings may also support the additional substrate holding arrangement in such a way that it can be moved between the additional lock chamber and the coating chamber.

A method of manufacturing a display apparatus includes: sequentially fixing a display substrate and a mask assembly to a carrier; transporting the mask assembly and the display substrate to a deposition unit via the carrier; and depositing a deposition material on the display substrate by passing the deposition material through the mask assembly, by using the deposition unit.

According to one embodiment, a film formation apparatus that suppresses effects of pre-processing and enables stable film formation is provided. A film formation apparatus of the present disclosure includes a chamber that can be made vacuum, a transporter that is provided inside the chamber and that circulates and transports a workpiece in a trajectory of a circle, a film formation unit that forms film by sputtering on the workpiece circulated and transported by the transporter, a load-lock room that loads the workpiece into and out of the chamber relative to air space while keeping an interior of the chamber vacuum, and a pre-processing unit that is provided in the chamber at a position adjacent to the load-lock room and that performs pre-processing to the workpiece loaded in from the load-lock room in a state distant from the transporter.

An apparatus for accommodating an article in a vacuum-coating installation has a carrier with a coating opening and a retaining device for retaining the article in the coating opening. The retaining device has a pivot bearing that is secured on the carrier and a pivot axis, about which it is possible to pivot the retaining device to thereby turn the article in the coating opening. The pivot bearing has a bearing body with a circumferentially closed mount for a round body, which extends in the direction of the pivot axis, wherein the bearing body has a circumferentially closed mount and a circumferentially open mount for the round body, and therefore, when the retaining device is arranged on the carrier, the round body can be introduced through the circumferentially open mount into the circumferentially closed mount.