A stage device for holding a substrate in a processing apparatus for processing the substrate includes a stage, a stage rotating mechanism, and a cold heat transfer mechanism. The stage is configured to hold the substrate in a processing chamber. The stage rotating mechanism includes a rotation shaft extending downward from a center of a bottom surface of the stage and a motor configured to rotate the stage via the rotation shaft. The cold heat transfer mechanism includes at least one cold heat transfer body that is fixedly disposed at a position spaced away from the rotation shaft below the stage and is configured to transfer cold heat of a chiller. The cold heat transfer mechanism is disposed with a gap between the cold heat transfer mechanism and the stage.

There is provided a cathode unit for a sputtering apparatus, having a construction in which a target can be replaced without opening a vacuum chamber to the atmosphere. The cathode unit having targets and being adapted to be mounted on a vacuum chamber has: a supporting frame mounted on an external wall of the vacuum chamber; an annular moveable base supported by the supporting frame in a manner to be movable toward or away from the vacuum chamber; a rotary shaft body rotatably supported by the movable base in a manner to be elongated through an inner space of the movable base in parallel with a sputtering surface of the target; provided an axial direction of the rotary shaft body is defined to be an X-axis direction, and a forward or backward direction orthogonal to the X-axis direction of the movable base is defined to be a Z-axis direction.

A movable structure includes a processing chamber configured to perform processing under a vacuum environment; a fixed portion disposed in the processing chamber; a movable portion that is movable with respect to the fixed portion; a transmission/reception module provided at the fixed portion and having a hermetically sealed structure; and a sensor module provided at the movable portion and having a hermetically sealed structure. The transmission/reception module and the sensor module perform transmission and reception of signals in a non-contact manner.

A film forming apparatus includes a chamber that is a container in which a sputter gas is introduced, a carrying unit provided inside the chamber, and circulating and carrying a work-piece on a trajectory of a circular circumference, and a film formation processing unit including a sputter source depositing, on the work-piece circulated and carried by the carrying unit, a film formation material by sputtering to form a film, and a dividing member dividing a film forming position where the film is formed on the work-piece by the sputter source. The dividing member is installed so as to divide the film forming position in a way that, in the trajectory of the circular circumference, a trajectory of passing through a region other than the film forming position performing the film formation is longer than a trajectory of passing through the film forming position performing the film formation.

A brake disk or drum has at least one working surface which opposes a braking member such as a brake pad or shoe. A plurality of spaced, raised island formations are provided across the working surface, with channels extending between the island formations. Each raised island formation has an outer surface which contacts a brake pad or brake shoe during braking.

A holding arrangement for supporting a substrate carrier and a mask carrier during layer deposition in a processing chamber is provided. The holding arrangement includes two or more alignment actuators connectable to at least one of the substrate carrier and the mask carrier, wherein the holding arrangement is configured to support the substrate carrier in, or parallel to, a first plane, wherein a first alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in a first direction, wherein a second alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in the first direction and a second direction different from the first direction, and wherein the first direction and the second direction are in the first plane.

A holding arrangement for supporting a substrate carrier and a mask carrier during layer deposition in a processing chamber is provided. The holding arrangement includes two or more alignment actuators connectable to at least one of the substrate carrier and the mask carrier, wherein the holding arrangement is configured to support the substrate carrier in, or parallel to, a first plane, wherein a first alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in a first direction, wherein a second alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in the first direction and a second direction different from the first direction, and wherein the first direction and the second direction are in the first plane.

Embodiments described herein generally relate to a susceptor support for supporting a susceptor in a deposition process. The susceptor support includes a shaft, a plate with a first major surface coupled to the shaft, and a support element extending from a second major surface of the plate. The plate may be made of a material that is optically transparent to the radiation energy from a plurality of energy sources disposed below the plate. The plate may have a thickness that is small enough to minimize radiation transmission loss and large enough to be thermally and mechanically stable to support the susceptor during processing. The thickness of the plate may range from about 2 mm to about 20 mm.

Embodiments described herein generally relate to a susceptor support for supporting a susceptor in a deposition process. The susceptor support includes a shaft, a plate with a first major surface coupled to the shaft, and a support element extending from a second major surface of the plate. The plate may be made of a material that is optically transparent to the radiation energy from a plurality of energy sources disposed below the plate. The plate may have a thickness that is small enough to minimize radiation transmission loss and large enough to be thermally and mechanically stable to support the susceptor during processing. The thickness of the plate may range from about 2 mm to about 20 mm.

The present disclosure provides an impregnation method that includes the steps of providing a workpiece to be impregnated, placing the workpiece in a bath of impregnating agent inside a vessel, and oscillating movement of a vibrating body inside the vessel during an impregnation period. The vibrating body creates oscillating pressure changes inside the bath by acting on the bath. the method further includes removing the workpiece from the bath after the impregnation period.