A grid guidance device for guiding battery grids to a battery pasting machine. The grid guidance device includes an assemblage of components that work together to adjust a position of a platform relative to a pasting orifice of the battery pasting machine. The platform receives the battery grids over it amid use of the grid guidance device. Multiple electric motors can be provided to rotate shafts for making the position adjustments. The position adjustments can involve one or more of the following: lateral positioning of the battery grids relative to the pasting orifice, advancement and retraction positioning of the platform relative to the pasting orifice, and/or raising and lowering positioning of the platform relative to the pasting orifice.

A battery paste application tooling assembly includes a hopper, a connector assembly, and a clamp assembly. The battery paste application tooling assembly can be equipped in a pasting machine. The hopper receives battery paste material. The hopper has an orifice plate with an orifice therein. The connector assembly is engageable with the orifice plate and disengageable therefrom. The clamp assembly is movable between a first position and a second position. In the first position, the clamp assembly releasable secures the orifice plate to the hopper. In the second position, the clamp assembly permits removal of the orifice plate from the hopper.

A resin applicator including a pair of transfer rings that are arranged so that transfer surfaces face each other via a clearance; at least one resin supply that supplies an ultraviolet cure resin to the transfer surfaces of the transfer rings; and at least one ultraviolet light source that supplies an ultraviolet ray to at least the clearance.

Embodiments of the present disclosure relate to arrangements for simulating creping of tissue and methods for simulating creping of tissue.

Systems for the manufacturing of waveguide cells in accordance with various embodiments can be configured and implemented in many different ways. In many embodiments, various deposition mechanisms are used to deposit layer(s) of optical recording material onto a transparent substrate. A second transparent substrate can be provided, and the three layers can be laminated to form a waveguide cell. Suitable optical recording material can vary widely depending on the given application. In some embodiments, the optical recording material deposited has a similar composition throughout the layer. In a number of embodiments, the optical recording material spatially varies in composition, allowing for the formation of optical elements with varying characteristics. Regardless of the composition of the optical recording material, any method of placing or depositing the optical recording material onto a substrate can be utilized.

To provide surface treatment that can reduce occurrence of defects caused by incorporation of dust. Rollers 40 are rotatably fixed to rotating shafts 72 provided to protrude from lateral protective walls 49. The lateral protective walls 49 are fixed perpendicularly to lower protective walls 47 fixed to outer walls 39. Hanging plates 64 of a hanger 50 extend through a space 43 between both lower protective walls 47 and support clips 52. A liquid 41, such as water, is filled in spaces defined by the lateral protective walls 49, the lower protective walls 47, and the outer walls 39. The liquid 41 is filled to cover about half of each rotating shaft 72. Thus, fine dust generated by a transferring mechanism is captured by the liquid 41 and prevented from drifting from the space 34 toward the substrate 54.

A slot-die coating apparatus for manufacturing a patterned coating layer (3) on a substrate surface (1s) of a substrate (1) comprises a slot-die coating head (2), a controlled coating fluid supply system (7) and a substrate carrier (6) for carrying the substrate (1). The slot-die coating head (2) comprises an inlet (21) for receiving coating fluid from the coating fluid supply system and a slit-shaped outflow opening (22) that is communicatively coupled to the inlet and has a slit direction. The controlled coating fluid supply system (7) alternately operates in a first mode (M1) to provide for a flow of coating fluid out of the slit-shaped outflow opening (22) for deposition on the substrate surface and in a second mode (M2) wherein a deposition of coating fluid out of the slit-shaped outflow opening (22) on the substrate surface is interrupted (21). The coating head (2) has an internal coating fluid trajectory extending from the inlet (21) to the slit-shaped outflow opening (22). In a stream-downwards order, the coating fluid trajectory comprises a lateral distribution portion (23) to distribute a flow of fluid over said slit direction, a collection channel (24) extending transverse to the stream-downwards direction, and a flow resistive output portion (25). Upon a transition from the first mode (M1) to the second mode (M2) the coating fluid supply system (7) sucks coating fluid from at least one outlet (26) of the slot-die coating head (2) that is communicatively coupled to the collection channel (24).

An automated insulation application system that includes a robotic arm and an insulation end effector coupled at a distal end of the robotic arm, the insulation end effector configured to apply insulation material to a target surface. The system can further include a computing device executing a computational planner that: generates instructions for driving the insulation end effector and robotic arm to perform at least one insulation application task that includes applying insulation material via the insulation end effector to a target surface, the generating based at least in part on obtained target surface data; and drives the end effector and robotic arm to perform the at least one insulation application task.

An automated drywalling system for applying joint compound or plaster to drywall pieces. The system includes a robotic arm and a mudding end effector coupled at a distal end of the robotic arm, the mudding end effector configured to apply joint compound or plaster to a target surface. The system can further include a computing device executing a computational planner that: generates instructions for driving the mudding end effector and robotic arm to perform at least one mudding task that includes applying joint compound or plaster, via the mudding the end effector, to one or more joints between a plurality of drywall pieces, the generating based at least in part on obtained target surface data; and drives the end effector and robotic arm to perform the at least one mudding task.

A treatment solution supply apparatus to supply a treatment solution to a treatment solution discharge unit via a supply path that is provided with a filter configured to remove foreign substances in the treatment solution and a tubephragm pump to send the treatment solution, the supply path has an opening/closing valve on an upstream side of the tubephragm pump and the filter, and a suck-back valve on a downstream side of the tubephragm pump and the filter, and includes a control unit to control at least the tubephragm pump, the opening/closing valve, and the suck-back valve, wherein the control unit performs: a control of stopping sending of the treatment solution from the tubephragm pump; and a control of suspending discharge of the treatment solution from the treatment solution discharge unit by operation of the suck-back valve, and then closing the opening/closing valve to stop the discharge.