Abstract: Jet lines C1, C3, C5, . . . extending in an X-direction and suction lines C2, C4, C6, . . . extending in the X-direction are arranged alternately at a fixed pitch W in a Y-direction. Jet openings 88 are arranged at fixed intervals 3D on the jet lines C2n?1, suction openings 90 are arranged at fixed intervals 3D on the suction lines C2n, and the jet openings 88 and the suction openings 90 on the adjacent ones of the jet lines C2n?1 and the suction lines C2n are spaced apart from each other by a fixed distance D with respect to the X-direction. Slots 88a and 90a are extended straight from the upper ends of the jet openings 88 and the upper ends of the suction openings 90, respectively, in a carrying direction (the X-direction) and a direction opposite the carrying direction.

Abstract: The present invention provides a floating-type substrate conveying and processing apparatus that floats a substrate to be processed. The device includes a floating stage that floats the substrate, a liquid supplier placed above the floating stage via the substrate to supply a process liquid to a surface of the substrate, and a moving mechanism for holding the substrate as detachable at opposite ends of the substrate, at a floating height of the substrate, and for moving the substrate on the floating stage. The floating stage is formed of a porous member and has a plurality of suction apertures airtightly defined in a porous portion of the porous member. The floating stage injects gas through the porous portion and sucks gas through the suction apertures to float the substrate placed on the porous portion.

Abstract: Formation of banded irregularities in a process liquid film formed on a substrate being carried by a flotation carrying system is reduced or suppressed effectively. Jet lines C1, C3, C5, . . . extending in an X-direction and suction lines C2, C4, C6, . . . extending in the X-direction are arranged alternately at a fixed pitch W in a Y-direction. Jet openings 88 are arranged at fixed intervals 3D on the jet lines C2n?1, suction openings 90 are arranged at fixed intervals 3D on the suction lines C2n, and the jet openings 88 and the suction openings 90 on the adjacent ones of the jet lines C2n?1 and the suction lines C2n are spaced apart from each other by a fixed distance D with respect to the X-direction. Slots 88a and 90a are extended straight from the upper ends of the jet openings 88 and the upper ends of the suction openings 90, respectively, in a carrying direction (the X-direction) and a direction opposite the carrying direction.

Abstract: The present invention provides a floating-type substrate conveying and processing apparatus that floats a substrate to be processed. The device includes a floating stage that floats the substrate, a liquid supplier placed above the floating stage via the substrate to supply a process liquid to a surface of the substrate, and a moving mechanism for holding the substrate as detachable at opposite ends of the substrate, at a floating height of the substrate, and for moving the substrate on the floating stage. The floating stage is formed of a porous member and has a plurality of suction apertures airtightly defined in a porous portion of the porous member. The floating stage injects gas through the porous portion and sucks gas through the suction apertures to float the substrate placed on the porous portion.

Abstract: The coating material is supplied to a coating die provided with a manifold chamber, a draw-in chamber provided with a diaphragm, a supply passage and a discharge opening. The coating material is stored temporarily in the manifold chamber, is supplied through the supply passage to the discharge opening, and is discharged through the discharge opening onto the surface of the base sheet. The discharge of the coating material through the discharge opening is interrupted by deforming the diaphragm so as to form a draw-in chamber. The ball nut is driven by the servomotor so as to move the ball screw axially away from the supply passage to deform the flexible diaphragm so that the coating material is drawn into the draw-in chamber to interrupt discharging the coating material through the discharge opening. Thus, the coating material is applied intermittently to the substrate.

Abstract: The coating material is supplied to a coating die provided with a manifold chamber, a draw-in chamber provided with a diaphragm, a supply passage and a discharge opening. The coating material is stored temporarily in the manifold chamber, is supplied through the supply passage to the discharge opening, and is discharged through the discharge opening onto the surface of the base sheet. The discharge of the coating material through the discharge opening is interrupted by deforming the diaphragm so as to form a draw-in chamber. The ball nut is driven by the servomotor so as to move the ball screw axially away from the supply passage to deform the flexible diaphragm so that the coating material is drawn into the draw-in chamber to interrupt discharging the coating material through the discharge opening. Thus, the coating material is applied intermittently to the substrate.