A method for controlling a recirculation pump assembly is disclosed. The method includes receiving a process-dependent characteristic and determining a recirculation flow rate of adhesive that flows to the recirculation pump assembly based on the process-dependent characteristic. The method further includes determining a recirculation pump speed of the recirculation pump assembly for pumping the adhesive to a supply channel using the recirculation flow rate, and adjusting an operating speed of the recirculation pump assembly to match the recirculation pump speed. A system and storage device for performing the above method are also disclosed.

A variety of dispensing manifolds which are removable connectable to a single deformable container having a single exit portion are disclosed. The dispensing manifolds of the present disclosure provide a single deformable container having a single exit with one or more outlets from which a fluid can be controllably dispensed. The present disclosure also provides a single force generation mechanism, a deformable container holding a fluid or substance, and dispensing mechanisms all on one machine, i.e., a carrier; a system that may also include a pressurized air source that assists a flow of a fluid; and a system that allows for a continuous flow a substance. The systems of the present disclosure provide a deformable container and a method of dispensing wherein, during dispensing, an actuation member is continuously free of contact with the fluid or substance within the container and the actuation member only contacts the exterior surface of the deformable container.

A substrate processing apparatus includes a chamber, a substrate holding part, a substrate rotating mechanism, and a processing liquid supply part. The chamber includes a chamber body and a chamber cover, and the chamber cover is moved up and down by a chamber opening and closing mechanism. A top plate is attached to the chamber cover. While the chamber cover is in contact with the chamber body, a sealed space is formed and processing is performed. When the chamber cover is moved up, an annular opening is formed between the chamber cover and the chamber body. A cup part is positioned outside the annular opening. A processing liquid spattering from a substrate is received by the cup part.

A variety of dispensing manifolds which are removable connectable to a single deformable container having a single exit portion are disclosed. The dispensing manifolds of the present disclosure provide a single deformable container having a single exit with one or more outlets from which a fluid can be controllably dispensed. The present disclosure also provides a single force generation mechanism, a deformable container holding a fluid or substance, and dispensing mechanisms all on one machine, i.e., a carrier; a system that may also include a pressurized air source that assists a flow of a fluid; and a system that allows for a continuous flow a substance. The systems of the present disclosure provide a deformable container and a method of dispensing wherein, during dispensing, an actuation member is continuously free of contact with the fluid or substance within the container and the actuation member only contacts the exterior surface of the deformable container.

A substrate processing apparatus includes a chamber, a substrate holding part, a substrate rotating mechanism, and a processing liquid supply part. The chamber includes a chamber body and a chamber cover, and the chamber cover is moved up and down by a chamber opening and closing mechanism. A top plate is attached to the chamber cover. While the chamber cover is in contact with the chamber body, a sealed space is formed and processing is performed. When the chamber cover is moved up, an annular opening is formed between the chamber cover and the chamber body. A cup part is positioned outside the annular opening. A processing liquid spattering from a substrate is received by the cup part.

A substrate processing apparatus includes a chamber, a substrate holding part, a substrate rotating mechanism, and a processing liquid supply part. The chamber includes a chamber body and a chamber cover, and the chamber cover is moved up and down by a chamber opening and closing mechanism. A top plate is attached to the chamber cover. While the chamber cover is in contact with the chamber body, a sealed space is formed and processing is performed. When the chamber cover is moved up, an annular opening is formed between the chamber cover and the chamber body. A cup part is positioned outside the annular opening. A processing liquid spattering from a substrate is received by the cup part.

An applicator for introducing a fluid to a plant includes a first arm and a second arm pivotally connected to one another at one end. The other ends are spaced apart to receive the plant therein when the applicator is in a rest position and are driven together upon pivoting of the arms to place the applicator in an application position. A fluid injector is mounted on the first arm and includes an injector body and a diaphragm defining a plurality of channels. The diaphragm includes a pliable dome defining a reservoir to receive the fluid and a plurality of applicator nodes. A respective applicator node is positioned near a terminus of each channel. A driving member engages the pliable dome when the applicator is pivoted to the application position. The pliable dome is then compressed by the driving member to direct the fluid through the plurality of channels.

An inner plate assembly for arrangement between top and bottom plates of an applicator for applying fluid-based chemicals to traveling sheets of textile substrates includes a plurality of interlocking plate segments. Each interlocking plate segment includes an outer frame segment and one or more baffle member segments supported by the outer frame segment. Each interlocking plate segment further includes a first interlocking structure disposed at a first end thereof and a second interlocking structure at a second, opposite end thereof to facilitate end-to-end interlocking arrangement of the plurality of interlocking plate segments.

A dispensing apparatus (1) for delivering droplets of fluids such as liquids having a low viscosity or being soft gels onto poultry hatchlings that are present in movably mounted hatchling trays (19) comprising at least one reservoir (18), at least one pumping unit (9), connected to at least one reservoir (18), with at least one manifold (8) connected to at least one pumping unit (9), as well as a control unit. The apparatus comprises a plurality of optionally adjustable fluid atomizers (6) being connected by flexible connecting means (7) to at least one manifold (8), whereby the fluid atomizers (6) are detachably and/or slidably connected on at least one mounting rail (5), and that optionally different types of fluid atomizers (6) are distributed onto the mounting rail (5). Additionally, a method for delivering fluid droplets onto poultry hatchlings present in moving hatchling trays (19) is described.

A method for pumping, tracking, and controlling a fluid includes the steps of producing a drive signal for driving a motor of a pump using a controller, driving the motor to pump a fluid based on the drive signal, sending a dispense signal from the controller to a sprayer for dispensing the fluid, determining a work piece count as a function of a work piece signal provided to the controller from the work piece sensor, detecting the position of a rod connected to the motor and the pump using a position sensor, creating a position signal as a function of the position of the rod using the position sensor, sending the position signal to the controller, and determining a volume usage as a function of the position of the rod using the controller.