Abstract: The present apparatus and system relate to a machine and components thereof adapted to fill packages and which may be utilized according to a method. The machine progresses a package via a conveyor through sub-stations, such as a cone trimmer, product conveyor, packing head, folding station, and injection station. The cone trimmer trims the package to a desired length, the product conveyor deposits product into the packing head, the packing head packs the product in the package, the folding station folds the package, and the injecting station injects the package.

Abstract: The technology described herein generally relates to an automated packaging apparatus, system and method that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus uses a packing method to accurately fill the cones, pack the crumbled leaves into the cones, and close the wide top portion of the cone into a precise shape.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final packed containers. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus provides a system for reliably and accurately depositing or injecting a fluid into a cone packed with loose particulate.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: A showerhead assembly including a plurality of scanner nozzles. Each scanner nozzle includes an oscillation chamber fluidly coupled to an inlet aperture and an outlet aperture, and configured to discharge a random sweeping jet from the outlet aperture over a coverage area.

Abstract: The technology described herein generally relates to particular form of folded package. The package packages loose particles into a conical container and secures the filling with a folded distal end. More specifically, loose plant matter, such as crumbled dried leaves, are supplied as filling and the package may further be provided with a fluid core.

Abstract: A fluidic nozzle of the scanner type has its outlet spray pattern skewed from its chamber axis (A) by an amount determined by the asymmetry of its outlet orifice (23, 33) about that axis. A spray assembly (70, 90) of such nozzles, such as a showerhead, can be designed using nozzles with selected pattern skew angles to achieve desired spray coverage. Indexing tabs (97) and slots (96) are used to angularly position the nozzles in the showerhead. A portion of each nozzle may be formed with the showerhead faceplate (71) as an integral piece.

Abstract: A clog resistant in-line vortex emitter and drip irrigation assembly and method uses a double-sided circuit and a series of vortex chambers of optimized dimensions to create a pressure drop with large dimensions and good clog resistance. The vortex chamber 100 also allows for a lower exponent than traditional circuits. This gives a pressure regulating property to the no-moving-parts circuit. The vortex emitter allows for some pressure regulation without sacrificing recyclability or requiring moving parts. The vortex circuit of the present disclosure is optimized for an emitter efficiency Ef value wherein Ef=(k/Ackt)*Amin such that k is a unitless head loss coefficient, Ackt is the area of the circuit, and Amin is the minimum cross sectional area of the circuit. A higher k per a given area with larger dimensions allows for a smaller part with a lower chance of clogging.

Abstract: A flow-restricted compound spray generating device 100 includes a spray face member 120B including at least one fluidic circuit oscillator defining geometry 132 including an outlet orifice 138 in the spray face member's central area configured to aim an oscillating spray 300 having a selected oscillating spray thickness distally along a spray axis 112. The spray face member 120B also includes a plurality of non-oscillating (e.g., laminar or jet) spray generating orifices 160B arrayed evenly around the spray face member's periphery to aim a plurality of non-oscillating laminar or jet sprays 302 distally along the spray axis 112 to provide a ring of high velocity streams arrayed around the central oscillating spray 300 to generate a compound spray 310 with an outflow which has a pleasing spray density with an apparent outflow thickness which is substantially equal to the spout orifice's diameter 320.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: A clog resistant in-line vortex emitter and drip irrigation assembly and method uses a double-sided circuit and a series of vortex chambers of optimized dimensions to create a pressure drop with large dimensions and good clog resistance. The vortex chamber 100 also al lows for a lower exponent than traditional circuits. This gives a pressure regulating property to the no-moving-parts circuit. The vortex emitter allows for some pressure regulation without sacrificing recyclability or requiring moving parts. The vortex circuit of the present disclosure is optimized for an emitter efficiency Ef value wherein Ef=(k/Ackt)*Amin such that k is a unitless head loss coefficient, Ackt is the area of the circuit, and Amin is the minimum cross sectional area of the circuit. A higher k per a given area with larger dimensions allows for a smaller part with a lower chance of clogging.

Abstract: A new scanner fluidic oscillator is used in an economically manufactured fluidic showerhead or nozzle assembly 50, 198, 250, 400 which aims oscillating sprays from multiple scanner fluidics to spread water uniformly over a preselected coverage area. The scanner fluidics and showerhead of the present invention provide a pleasing spray pattern, droplet size, droplet velocity, and temperature uniformity at very low flow rates (i.e., 2 gpm or less) for showering. The scanner fluidics are provided in a plurality of distinct configurations for generating individually tailored scanning sprays having a selected scanning spray characteristics. The showerhead's front plate (e.g., 56, 200, 270, 454) is configured to support and aim the fluidic oscillators, optionally with indexing slots 802 configured to receive corresponding angular indexing tabs 800 on the fluidic oscillator inserts to orient and aim the spray from each fluidic oscillator (e.g., 172, 220,282, 530).

Abstract: Spray nozzle assembly (300) is configured to generate a swirled spray (312) with improved rotating velocity w and smaller uniform droplet size. Cup-shaped nozzle member (300) has a body portion (318) with a cylindrical side wall (320) surrounding a central longitudinal spray axis (322), a circular closed end wall (324) and an exit aperture (310) coaxial with the spray axis (322) and defined through the end wall (324). A fluid dynamic circuit (330) is formed in an inner surface (326) of end wall (324) and includes three inwardly tapered power nozzles (302, 304, 306) terminating in an interaction region (308) which is exhausted via the exit aperture (310). The power nozzles have respective longitudinal axes (334, 362, 382) offset with respect to the spray axis (322) with corresponding non-tangential angles of attack (352, 374, 394) configured to efficiently cause a fluid vortex in interaction region (308).

Abstract: A multiple-fluidic circuit substrate structure with an integral inter-circuit bypass lumen effectively provides multiple parallel filtered fluid inlets having filtered fluid outlets with at least one inter-circuit pass-through channel in fluid communication between the filtered fluid outlets to automatically provide full flow of filtered fluid to each of a plurality of fluidic circuits or to two or more circuits even if one fluidic circuit's corresponding inlet fluid filter is clogged.

Abstract: A fluidic scanner nozzle comprising an interaction chamber defined between an upstream end and a downstream end with a longitudinal chamber axis. The upstream end having an inlet opening for receiving and delivering pressurized fluid into said interaction chamber along said chamber axis. The downstream end having an outlet orifice for issuing a generally conical outlet spray of liquid droplets from said chamber into ambient environment and an axial gap positioned between said upstream end and said downstream end. The upstream and downstream ends may define inner cavities having a hemisphere shape. The axial gap may define a cylindrical sidewall segment aligned between an upper hemisphere shaped inner cavity and a lower hemisphere shaped inner cavity. The axial gap includes a selected axial length and an inside diameter that may be either a continuous axial gap or a stepped axial gap.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.

Abstract: The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final folded packages. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus packs the crumbled leaves into the cones, closes the wide top portion of the cone into a precise shape, and then runs a quality control check to ensure that the final filled cone meets preset specifications.