A multi-tiered precision powder coating batch system configured to enable simultaneous preparation of a first and second batch of powder coatings. The multi-tiered precision powder coating batch system including a plurality of storage bins configured to store a corresponding plurality of raw materials for preparation of batches of powder coatings, each of the storage bins including an automated dispenser configured to dispense a desired quantity of raw material within the storage bins into a corresponding first raw material container located on a first tier, and a second raw material container located on a second tier, and a robotic arm configured to sequence a transfer of the raw material contents of the first tier raw material containers into a first tier mixing container for preparation of a first batch of a powder coating, and to sequence a transfer of the raw material contents of the second tier raw material containers into a second tier mixing container for a simultaneous preparation of a second batch of a powder coating.

The invention relates to a device and a method for the metallic coating of a work piece with a mobile coating lance (20), by means of which a metal plasma jet can be generated to create the coating consisting of metal particles. According to the invention, an extraction hood (30) is provided, which at least encloses an axial section of the coating lance (20) in a ring-shaped manner, and the extraction hood (30) has a ring-shaped holding unit (50), which is configured to take up the metal particles.

The invention relates to a device and a method for the metallic coating of a work piece with a mobile coating lance (20), by means of which a metal plasma jet can be generated to create the coating consisting of metal particles. According to the invention, an extraction hood (30) is provided, which at least encloses an axial section of the coating lance (20) in a ring-shaped manner, and the extraction hood (30) has a ring-shaped holding unit (50), which is configured to take up the metal particles.

A method includes providing a reservoir of randomly oriented fibers in a solution, dispensing the solution of randomly oriented fibers through a nozzle having an orientation component onto a porous substrate as a solution of aligned fibers, and immobilizing the fibers to form a fiber pre-form. A system includes a porous substrate, a deposition nozzle, a reservoir of randomly oriented fibers in solution connected to the deposition nozzle, the deposition nozzle position adjacent the porous substrate and connected to the reservoir, the nozzle to receive the randomly oriented fibers and output aligned fibers, and a vacuum connected to the porous substrate to remove fluid from the porous substrate as the deposition nozzle deposits the aligned fibers on the porous substrate to produce a fiber pre-form having aligned fibers.

A method includes providing a reservoir of randomly oriented fibers in a solution, dispensing the solution of randomly oriented fibers through a nozzle having an orientation component onto a porous substrate as a solution of aligned fibers, and immobilizing the fibers to form a fiber pre-form. A system includes a porous substrate, a deposition nozzle, a reservoir of randomly oriented fibers in solution connected to the deposition nozzle, the deposition nozzle position adjacent the porous substrate and connected to the reservoir, the nozzle to receive the randomly oriented fibers and output aligned fibers, and a vacuum connected to the porous substrate to remove fluid from the porous substrate as the deposition nozzle deposits the aligned fibers on the porous substrate to produce a fiber pre-form having aligned fibers.

The present specification relates to a dough line for processing dough, specifically sheeted dough, having a conveyor, for conveying the dough, a sensor, for detecting the beginning of a dough piece at a detection point in the dough line, a controllable flour sifter, arranged above the conveyor, for depositing flour on the conveyor or on dough on the conveyor, a controller, for controlling the amount of flour deposited by the flour sifter based on the sensor signal, wherein the controller is configured for disabling the flour sifter when there is no dough piece on or to be placed on the conveyor at the location of the flour sifter, enabling the flour sifter to deposit a first amount of flour per amount of displacement of the conveyor when there is a dough piece on or to be placed on the conveyor at the location of the flour sifter.

The present specification relates to a dough line for processing dough, specifically sheeted dough, having a conveyor, for conveying the dough, a sensor, for detecting the beginning of a dough piece at a detection point in the dough line, a controllable flour sifter, arranged above the conveyor, for depositing flour on the conveyor or on dough on the conveyor, a controller, for controlling the amount of flour deposited by the flour sifter based on the sensor signal, wherein the controller is configured for disabling the flour sifter when there is no dough piece on or to be placed on the conveyor at the location of the flour sifter, enabling the flour sifter to deposit a first amount of flour per amount of displacement of the conveyor when there is a dough piece on or to be placed on the conveyor at the location of the flour sifter.

A build material management system for an additive manufacturing system is described in which a recovered build material tank (208) and a mixing tank (212) are provided. The recovered build material tank (208) comprises an outlet and a first build material filter (218b) for separating a gas flow from a build material flow. The mixing tank (212) comprises a second build material filter (218c). The mixing tank (212) is connected to the recovered build material tank (208) via a RBMT-to-mixer conduit (286). A controller (295) is provided to couple the second build material filter (218c) to a reduced pressure interface to transport build material from the outlet of the recovered build material tank into the mixing tank (212) via the second build material filter (218b). The controller (295) controls coupling of the first build material filter (218b) to the reduced pressure interface to transport build material from a build material source into the recovered build material tank (208). A corresponding method is provided.

An apparatus applies product and includes a pivotal platform solely supported through bushings formed of compressible material. The ground speed can be locked by stepping on a step pivoting a composite block to engage with an engagement of the transmission proportioner arm. A gate is opened utilizing a control lever pivotally mounted to a pivotably mounted control block to either engage or avoid a tang of an adjustment guide. A drive belt system includes a variator having first and second sheaves having variable effective diameters when their pivot pin is moved by pivoting a lever. A spray tip sprays a fan style spray at a small acute angle to the application area. A flip shield is pivoted about an axis parallel to the movement direction and includes a linear straight portion parallel to the axis in a redirection position.

An apparatus applies product and includes a pivotal platform solely supported through bushings formed of compressible material. The ground speed can be locked by stepping on a step pivoting a composite block to engage with an engagement of the transmission proportioner arm. A gate is opened utilizing a control lever pivotally mounted to a pivotably mounted control block to either engage or avoid a tang of an adjustment guide. A drive belt system includes a variator having first and second sheaves having variable effective diameters when their pivot pin is moved by pivoting a lever. A spray tip sprays a fan style spray at a small acute angle to the application area. A flip shield is pivoted about an axis parallel to the movement direction and includes a linear straight portion parallel to the axis in a redirection position.