A slurry scraping mechanism and an applying and scraping device used in an SG abrasive production process includes a scraping master support; a scraper, wherein the scraper is connected with the scraping master support through a suspension component such that the scraper is suspended, and a damping spring is arranged in the suspension component; and a torsion spring adjusting component, wherein the torsion spring adjusting component includes a plurality of torsion springs supported by a torsion spring support shaft, the torsion spring support shaft is fixed to the scraping master support, the torsion spring support shaft is movable up and down relative to the scraping master support, the torsion springs are clamped in a V-shaped plate, an end side of the V-shaped plate is connected with the scraping master support, and a side surface of the V-shaped plate is connected with the scraper.

A sealant discharging nozzle includes a nozzle body, a flat surface, a nozzle positioning portion, and a locating pin. The flat surface is provided on the nozzle body and is formed on a discharge port side of a through hole that extends along a central axis of the nozzle body. The nozzle positioning portion includes a pair of tapered surfaces disposed on both sides of the flat surface in a width direction of the flat surface. The locating pin is formed between the pair of tapered surfaces.

A dispensing system comprises a first dispenser and a second dispenser each including a first end, a second end, a longitudinal axis extending through the first end and the second end, and a set of nozzles arranged about the longitudinal axis. The first dispenser is positioned relative to the second dispenser such that the longitudinal axis of the first dispenser is non-coaxial with the longitudinal axis of the second dispenser. The dispensing system also comprises a substrate chuck configured to hold a substrate and a rotation mechanism configured to rotate the substrate chuck around a rotation axis or configured to rotate the first dispenser and the second dispenser around the rotation axis.

A die for coating an insulating liquid may include a die body configured to be positioned on a current collector with a certain space and discharge an insulating liquid; and a discharge portion configured to be formed on one surface where the insulating liquid of the die body is discharged, and form a discharge path and a discharge port where the insulating liquid is discharged, wherein the discharge portion includes a first discharge portion positioned at a front region side of a coating direction of the insulating liquid, and a second discharge portion positioned at a rear region side of the coating direction of the insulating liquid, an insulating liquid discharge path is formed between the first discharge portion and the second discharge portion, and an insulating liquid discharge port is formed between an end of the first discharge portion and an end of the second discharge portion.

A viscous material wiping device wipes the viscous material attached to the tip of a spatula with a sheet. A sheet support jig has a groove recessed in the sheet facing surface, the groove includes a receiving portion and a wiping portion that are continuous in the groove extending direction, and the wiping portion has a groove width smaller than that of the receiving portion and substantially equal to the outer dimension of the tip of the spatula. A controller drives the moving mechanism to position the spatula on the opposite side of the sheet supporting jig with respect to the sheet in a posture that the spatula extends parallel to the groove extending direction and overlaps the groove when viewed in a normal direction of the sheet facing surface, and move the spatula in the normal direction so that the tip of the spatula is received in the receiving portion by pressing the sheet against the groove with the spatula. The spatula is configured to move in the groove extending direction so that the tip of the spatula passes through the wiping portion.

A metering device is disclosed for regulating the depth of a flowable product coating a surface movable relative to the metering device by directing an air curtain towards the surface. The metering device comprises a body having an interior chamber, an inlet for connecting the chamber to a source of gas under super-ambient pressure; and an opening communicating with the chamber and having a mouth through which gas is discharged from the chamber towards the surface to form the air curtain. A porous or reticulated membrane is secured to, or formed integrally with, the body of the device to lie in the path of the gas discharged through the mouth of the opening.

An additive manufacturing device includes a recoater configured to push powder onto a build platform. The recoater defines an advancing direction for pushing powder. A first baffle is mounted to a first end of a leading edge of the recoater and a second baffle mounted to a second end of the leading edge of the recoater opposite the first end. Each of the first and second baffles includes a base mounted to the recoater, a first wall that extends obliquely ahead of and laterally outward from the base relative to the advancing direction, and a second wall opposite the first wall. The second wall extends obliquely ahead of and laterally inward from the base relative to the advancing direction. A volume is defined between the first and second wall with capacity to collect powder as the recoater advances.

An additive manufacturing device includes a recoater configured to push powder onto a build platform. The recoater defines an advancing direction for pushing powder. A first baffle is mounted to a first end of a leading edge of the recoater and a second baffle mounted to a second end of the leading edge of the recoater opposite the first end. Each of the first and second baffles includes a base mounted to the recoater, a first wall that extends obliquely ahead of and laterally outward from the base relative to the advancing direction, and a second wall opposite the first wall. The second wall extends obliquely ahead of and laterally inward from the base relative to the advancing direction. A volume is defined between the first and second wall with capacity to collect powder as the recoater advances.

A dispensing system comprises a first dispenser and a second dispenser each including a first end, a second end, a longitudinal axis extending through the first end and the second end, and a set of nozzles arranged about the longitudinal axis. The first dispenser is positioned relative to the second dispenser such that the longitudinal axis of the first dispenser is non-coaxial with the longitudinal axis of the second dispenser. The dispensing system also comprises a substrate chuck configured to hold a substrate and a rotation mechanism configured to rotate the substrate chuck around a rotation axis or configured to rotate the first dispenser and the second dispenser around the rotation axis.

An apparatus for dispensing a flowable material is disclosed. The apparatus comprises a rotary actuator, a reservoir, containing a hydraulic fluid, a piston, movable inside the reservoir, a linear actuator, coupled to the piston, a gear train, coupling the rotary actuator with the linear actuator, and a flowable-material dispenser, hydraulically coupled with the reservoir.